KR830000500B1 - Playback device - Google Patents

Abstract

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Description

Playback device

1 is a block diagram of a playback apparatus having a nonlinear hole correction stage embodying the principles of the present invention;

FIG. 2 is a partial block circuit diagram showing one embodiment of the nonlinear hole correction device shown in FIG.

3 is a circuit diagram showing an embodiment of the position sensor shown in FIG.

4 is a circuit diagram showing one embodiment of the bias generator shown in FIG.

FIG. 5 is a partial block circuit diagram of one embodiment of the servo device shown in FIG.

FIG. 6 is a partial block circuit diagram of another embodiment of the nonlinear hole correction equivalent shown in FIG.

FIG. 7A shows frequency response characteristics of the signal shaping circuit shown in FIG. 6. FIG.

FIG. 7B is a diagram showing the frequency response characteristic of the differential device shown in FIG.

FIG. 7c shows the overall frequency response of the nonlinear hole correction device shown in FIG.

The present invention relates to a novel nonlinear system, and more particularly to a disc record reproducing apparatus using the novel nonlinear system.

In US Pat. No. 3,842,194, a variable capacity video disc playback system is described. According to the configuration, the information track is composed of geometric changes (dimension shape changes) at the bottom of the spiral grooves formed in the disk having, for example, the surface of the conductive material covered with a thin film of dielectric material.

Although not described in this US patent, in another form, the disc is made by filling a PVC (polyvinyl chloride) base with a conductive material, such as carbon. The capacitance generated between the conductive electrode of the tracking reproducing needle for estimating the information track and the conductive material of the disk changes with the rotation of the disk by the disk support turntable. At this time, this capacity change is detected and the recorded information is reproduced.

In one form for the wire groove information track described in the above U.S. patent, the recesses and recesses of the groove bottoms extending across the groove bottoms are alternated, and the alternating frequencies vary according to the video amplitude to be recorded. The recorded signal thus takes the form of a carrier frequency modulated in accordance with the video signal.

One technique for recording desirable information on a video disc disc is described in US Pat. No. 3,943,302. Also described in US Pat. No. 4,044,379 is a technique for improperly-mechanically recording preferred information onto a video disc disc.

The recording of a composite color video signal with speech is accomplished by frequency modulating a low frequency speech carrier over a range of low frequency shifts (e.g., 716 KHz ± 50 KHz) with the accompanying speech signal. In an image carrier modulator, a composite color video signal frequency modulates a high frequency image carrier over a certain high frequency shift range (for example, 4.3 to 6.3 KHz). The composite color video signal includes a luminance signal occupying a predetermined frequency band and a chrominance signal appearing as a side wave component of a chrominance subcarrier modulated by the luminance signal component interpolated in the middle region of the predetermined band. The peak-peak amplitude of the audio modulator output is kept at a low level compared to the peak-peak amplitude level of the image modulator output. The ratio of these levels is 1:10, for example. Each modulated carrier is combined in a linear adder and applied to a recording device. As such a recording apparatus, an electromechanical apparatus, an optical apparatus, or an electronic beam recording apparatus controlled in response to a signal generated by the adder is used. Up to now, two signal formats, namely, the linear sum of the voice and the video carrier and the linear sum are limited, have been used to form a square wave duty cycle modulated by the voice carrier and frequency modulated by the video information. The present invention can be used in either of these two forms. Linear signal format will be used to illustrate the operation of the present invention.

A recording apparatus is used in which the recording signal is a linear sum of a low frequency audio carrier and a high frequency video carrier so that the desired information is recorded on the disc. In one embodiment, the disk made by such a recording technique has a spiral groove having a bottom portion with an unevenness representing the recorded signal.

A stamper disc is made from a recording disc in a technique as described in US Pat. No. 3,342,194, and this stamper disc is used in a record stamping machine, whereby a plurality of replica discs of thermoplastic material are made. Each of these duplicated discs has an information track made of irregularities recorded on the disc disc.

In the playback of a video disc record having the above-described signal format, under certain circumstances, the reproduced video signal may exhibit interference by voice, and the reproduced audio signal may show interference by the video signal, which may cause discomfort to the viewer. . Tracking of uneven patterns on the disc by an ideal transducer produces the same electrical signal as the signal recorded on the disc. However, until now, it is known that the signal taken out from the disc by the reproducing converter is distorted. The distortion of such a signal may be nonlinear or linear. Nonlinear distortions interfere with both reproduced speech and video signals.

One possible explanation of audio interference in video signals associated with a playback device having a transducer of the type having a support of dielectric material and a conductive electrode is as follows. That is, the dielectric support portion of the regeneration needle is preferably longer in length (according to the information track) than the conductive electrode portion. In addition, since the signal recorded in the bottom of the groove is a linear sum of a high frequency signal, a low frequency signal, and a low frequency signal, the bottom of the groove is represented as a low frequency slowly changing voice carrier in which the high frequency video signal is superimposed.

Thus, during playback of the record, the position of the bottom of the pick-up needle electrode (in the direction perpendicular to the plane of the record) is determined by the bottom height (voice top) of the stationary track at the audio signal amplitude peak supporting the dielectric portion of the needle. It is mainly decided. When the height of the government track bottom (between the audio top and the audio bend) changes, a gap occurs in the space between the electrode bottom of the needle and the track bottom.

U. S. Patent No. 3,842, 194 described above shows two regenerative needle structures, one of which is a symmetrical structure, in which a conductive electrode is sandwiched between dielectric support materials that extend symmetrically before and after. The other is an asymmetric structure, in which the regeneration needle electrode is composed of a dielectric material and a conductive coating provided on the back side of the support. This asymmetric regenerator needle is generally preferred because its manufacture is very simple.

During regeneration of the rotating disk, the high dielectric constant of the dielectric support portion of the asymmetric needle (eg, sapphire or diamond) causes the electric field from the needle to the disk to concentrate on the dielectric support side of the electrode. As a result, the needle sees a signal on the disk that is not directly underneath the electrode, that is, at an angle toward the approaching signal. The voice carrier thus advances the phase of the video signal more as the needle passes through the aforementioned voice curve than when the needle passes through the voice top.

Therefore, when the height of the track bottom is changed, phase modulation by audio accompanying the video signal causes undesirable audio interference (i.e., an effect of intermodulation between the video signal and the audio signal) on the reproduced video.

U.S. Patent No. 3,934,263 discloses a technique for deliberately introducing a phase shift of video information by audio information only when selected to record an information signal on a disc disk, thereby reducing unnecessary audio interference. This technique is noted in terms of the reduction of speech interference. Replica disks obtained by stamping molds made from such discs are often incompatible with other reproducing transducers (eg, pressure or optical transducers).

Video interference (nonlinear interference) listened to in voice cannot be explained as described above. One explanation for video interference is as follows. That is, the modulated video carrier is partially demodulated by the nonlinear nature of the needle to generate a baseband video signal. This baseband video signal is polymerized with the voice signal to cause interference in the voice.

According to the principle of the present invention, nonlinear compensation means, i.e., a hole correction device, is used in a reproduction device for reproducing information from a recording medium. In such a reproducing apparatus, information reproducing means having a nonlinear response characteristic causes nonlinear distortion in the form of interference in the information reproduced from the information accumulated in the recording medium. The nonlinear compensating means coupled to this information reproducing means operates to modify the reproduced signal so that interference is reduced.

In addition, according to the principles of the present invention, non-linear compensation means, i.e., a hole correction device, is used to compensate for the non-linear response characteristics of the pick-up needle of the video disc player.

Further, according to the principle of the present invention, reduction of undesirable interference during reproduction of a video disc is not performed by recording a special compensation signal in the disc record but by providing a nonlinear hole correction device in the disc player apparatus.

In one embodiment of the invention, a nonlinear hole correction device is used to reduce voice interference in the video. In still another aspect, a nonlinear hole correction device is provided to reduce video interference in speech.

In one embodiment of the present invention, voice interference in video is reduced by the use of a nonlinear device that phase shifts the reproduced video signal by the pick-up needle in accordance with the instantaneous level of the recorded voice carrier. In such an example, the phase shift is performed by applying the reproduced signal to the hole correction device formed as a parallel connection of the capacitor and the diode. In this case, the polarity and bias of the diode decreases the conductivity of the diode during the period when the instantaneous level of the input voice carrier falls below a predetermined value (i.e., when the needle is passing through the peak of voice). During the period, the signal is selected to substantially pass through the capacitor. After the signal passes through the capacitor, the video signal is in phase. Of course, if the input voice carrier is inverted so that the voice carrier level rises when the needle passes the voice peak, the polarity and bias of the diode are changed so that the phase advances with the rise of the level.

In another embodiment of the present invention, video interference in speech is reduced by providing a hole correction device formed of a nonlinear device for modulating a reproduced signal. In this embodiment, diodes with polarity and bias may be used to reduce the level of the baseband video signal that is polymerized with speech. The modulated speech signal picked up by the reproducing needle includes secondary distortions, as described above, and the biased diode substantially excludes these distortions.

In the above two embodiments, the nonlinear hole correction required to lower the specific interference level needs to be predicted to some extent accurately. However, the interference level during the reproducing operation is left to the composite of variables including various parameters at the time of recording, the content of the recorded signal, the line diameter of the information track, and other various parameters at the time of reproducing. Thus, under all possible circumstances, circuit parameters (ie, magnitude of bias, average input signal level, time constant of the circuit, etc.) that ensure complete interference cancellation over all reproduction periods are not simply selected.

However, for an interference level within a certain range, the interference is completely eliminated or reduced below a certain threshold, and for an interference level above a certain range, the interference level is reduced below a threshold at which the viewer cannot feel uncomfortable. Thus, even if no other interference reduction method is used, the interference is not at least very stringent, and if other reduction methods are additionally used, the requirements placed on the additional interference reduction method are alleviated), In addition, for an interference level below the predetermined range, a circuit parameter can be selected so that the correction thereof does not exceed the threshold value and thus becomes unpleasant in itself. According to one embodiment of the present invention, a hole correction device which is adjusted in advance in order to obtain the above-mentioned effect is used.

However, in another embodiment of the present invention, there are times when the hole correction device is to be adjusted according to the position of the track line to be reproduced. For example, in the case of a hole compensator consisting of a parallel connection of a capacitor and a diode, the bias of the diode is manually adjusted so that the voice bit is reduced when reproduction is performed for a continuous groove line band located inside a predetermined line. Also good. However, it is preferable to use a suitable control device that responds to the position so that the magnitude of the bias automatically increases continuously as the reproduction needle approaches the record center. In this case, the hole correction device is adjusted along the radial position of the needle with respect to the record, and not along the detected interference level. In another embodiment of the present invention, the hole compensator can be adjusted in response to interference detected at the output of the hole compensator, but preferably the hole compensator is adapted to a variation in the level of interference accompanying the signal to be processed. Means for continuously adjusting are provided. Means are also provided for sensing the level of interference in accordance with the modulated signal and for generating a control voltage in accordance with the sensed interference level. This control voltage is used, for example, for bias control of the nonlinear device, so that the hole correction of the signal is performed as described above in response to the detected interference level.

According to still another embodiment of the present invention, the input from the signal pickup circuit to the hole compensating device is prepared through a variable attenuation amplifier. The feedback loop couples the output of the hole compensator to the control input of the variable attenuation amplifier so that the long term average level of the input video signal to the hole compensator remains constant. The input signal to the hole correction autonomy is kept constant, and for example, hole correction is performed even on a large input signal generated by a needle that has become wider due to wear.

The present invention will be described with reference to the following drawings. Referring to FIG. 1, a video disc player 80 (e.g., in the form described in US Patent No. 3,842,194 above) includes a video disc having a swirling information track containing video signal information accompanied by audio signal information. A turntable 82 for rotatably supporting 84 is provided. In addition, the player 80 includes a carriage 86 that is horizontally moved in synchronization with the radial movement of the reproduction needle during playback. The carriage 86 has a loss to accommodate the cartridge 88 which houses the signal pickup needle. The pickup circuit 90, in response to the output of the signal pickup device, generates a signal representing the recorded information at its output terminal. The signal at the output terminal of the pickup circuit 90 may include audio interference in video information or video interference in audio. This pickup circuit 90 is of the type described in, for example, US Pat. No. 4,070,625.

The output of the pickup circuit 90 is sent to the nonlinear hole correction device 93. This hole correction device reduces the interference caused by the nonlinear response of the reproducing means. An embodiment of this hole correction device will be described later with reference to FIG.

The output of the nonlinear hole corrector is sent to a pair of bandpass filters 92 and 94. The image carrier bandpass filter 92 has a relatively wide passband including the deviation range of the high frequency image carrier (e.g., 4.3 to 6.3 MHz) and the indispensable adjacent sideband region and selectively selects the image carrier components of the recorded signal. Pass through, but do not pass the voice carrier component relatively. The voice carrier bandpass filter 94 has a relatively narrow passband including a shift range of a low frequency voice carrier (e.g., 716KHz ± 50KHz) and an indispensable adjacent sideband region, and the voice carrier component of the recorded signal. Pass selectively, but do not pass the video carrier components relatively.

The output of each bandpass filter 92,94 is sent to demodulators 96,98, respectively. The video demodulator 96 generates recorded video signal information, including the synchronization component, at its output terminal, and the audio demodulator 98 generates recorded audio signal information at its output.

The video signal processing apparatus 100 coupled to the image demodulator 96 separates chrominance information and luminance information. The composite video signal generator 102 recombines the chrominance information and the luminance information according to, for example, the NTSC scheme. The transmitter 106 receives a signal suitable for processing voice, luminance and chrominance information and supplying it to the color television receiver 106 in accordance with the information signal recorded on the video disc 84. Display and issue a voice. As an example, when a signal is supplied to an antenna terminal of a color television receiver, means for synthesizing the separated components to form a new synthesized signal are provided in a circuit in the transmitter 104. This new composite signal modulates the appropriate RF carrier. Transmission apparatus used to achieve the functionality of the transmitter 104 is shown, for example, in US Pat. No. 4,097,899. The position detector 91 and the switch 95 will be described with reference to FIGS. 2 and 3.

The operation of the nonlinear hole correction device will be described with reference to FIG. With the switch 110 closed and the switches 112, 114, and 115 open, the hole correction stage for reducing voice interference in the video consists of a nonlinear device 117 for causing a phase shift. do. As the nonlinear device 117, for example, a parallel connection of a capacitor and a diode, a varactor diode, or a combination of other devices can be used. The compensator 117 lies in the signal path between the pickup circuit 90 and the demodulator 96 in FIG. In the embodiment shown in FIG. 2, the compensator 117 is constituted by the parallel connection of the diode 118 and the capacitor 116. The diode 118 is forward biased at the bending point of its characteristic curve by the bias current supplied from the bias generator 120 through the bias resistor 122. Operation of the bias generator 120 is described with reference to FIG. During the period in which the voice level of the input signal changes in the negative direction in response to the occurrence of height fluctuations in the groove bottom, the conduction degree of the diode 118 decreases in proportion to it so that a part of the applied signal passes through the capacitor 116. Let's do it. Since the signal passing through the capacitor 116 means that the transmitted signal component is differentiated (and thus the phase of the signal is advanced), the combination of the capacitor 116 and the diode 118 can be applied to the applied baseband signal. It effectively modulates phase and amplitude according to the height variation of the groove bottom.

Hole correction for video interference in the audio accompanying the video is performed by another nonlinear device arranged in the signal path between the pickup circuit 90 and the filter 4 in FIG. In the embodiment of FIG. 2 this many non-linear device is configured as a diode 124. Diode 124 is forward biased to the bending point of its characteristic curve by the bias current supplied from bias generator 126 through bias resistor 128.

The bias generators 120, 126 preferably provide a variable diode bias level when the contacts of the switches 114 and 115 are closed. The feedback loop 142 is possible as follows. The bandpass filter 134 coupled to the output of the image PM demodulator 96 shown in FIG. 1 is tuned to pass a frequency (e.g., 716 KHz) at which audio interference exists. The voice interference signal is sent from the filter 134 to the peak detector 132. The output of the peak detector is coupled to the servo device 130 for the purpose of reducing voice interference. The output of the servo device is coupled to the input of the bias generator 120 through the closed contact of the switch 114. The bias generator 120 generates a DC bias output current in response to the output of the thruster device 130. Operation of the bias generator 120 and the servo device 130 will be described below with reference to FIGS. 4 and 5, respectively. The servo device adjusts the output of bias generator 120 to minimize voice interference. The output of bias generator 120 is used to control the bias of diode 118 such that the hole correction of the signal is adjustable. When the detected voice interference level is low, phase progression by the compensator 117 is limited so that the reproduced baseband signal is not subjected to unnecessary phase modulation. Conversely, when the detected audio interference level is high, the bias of the diode is changed so that the baseband is corrected by the compensator 117 so that an adequately quiet background is ensured in the image displayed according to the signal reproduced by the record reproduction. The phase progression of the signal is changed.

The feedback loop 144 functions like the feedback loop 142. Bandpass filter 140 coupled to the output of diode 124 is tuned to pass a frequency at which video interference exists (e.g., 1.53 MHz for color carriers, or 15 KHz for horizontal periodic signals, and video interference The signal is supplied to the peak detector 138. The output of the peak detector 138 is coupled to the servo device 136 for the purpose of minimizing video interference, and the output of the servo device is connected to the closed contact of the switch 115. Passes through and is coupled to the pressure of the bias generator 126. The bias generator 126 generates a direct current bias current in accordance with the output of the servo device 136. Operation of the bias generator 126 and the servo device 136 Will be described later with reference to Figures 4 and 5. The servo device 136 adjusts the output of the bias generator 126 so that video interference is minimized. Bo Gekkeum are to be adjusted and used to control the bias of the diode 124.

In the embodiment of the present invention corresponding to the system shown in FIG. 2 with the contacts of switches 114 and 115 closed, the bias magnitude of the diode can be programmed for a change in the level of interference. By using such a programmable device, reproduction with a small amount of interference can be performed. However, a system that is simpler than the system shown in FIG. 2 with the contacts of the switches 114 and 115 open, allows proper reproduction with reduced interference. Over the entire period of record reproduction, fixing the bias of diode 118 (e.g., to 1.6V) reduces the average negative bead by 9 db.

In another embodiment of FIG. 2, the bias setting of the diode is programmed for a change in level depending on the position of the home line to be regenerated. The bias generators 120 and 126 are used to adjust the output of the bias generators 120 and 126 shown in FIG. 2 according to the position of the carriage 86 on the disk surface.

In FIG. 2, opening the switch 110 and closing the switch 112 deforms the system. In this modification, the input to the hole compensator at terminal X is supplied via variable attenuation amplifier 150. The output signal of the compensator 117 is fed back through a feedback loop that includes a bandpass filter 152. The bandpass filter 152 has a passband including the voice interference signal and its sideband, and its output is supplied to the peak detector 154. The output of the peak detector is applied to the control input of the variable attenuation amplifier 150 to keep the level of the input signal to the hole compensator constant. By keeping the input signal to the hole compensator constant, it is possible to ensure hole correction for a very large input signal caused by, for example, a worn needle.

3 shows one embodiment of the position sensor 91 shown in FIG. The movable contact 302 of the potentiometer 304 is attached to the carriage 86 of the video disc player 80 shown in FIG. A resistor 306 is coupled in series with the potentiometer 304, which is supplied with a positive DC voltage V _DD . At the terminal R 'coupled to the connection point of the resistor 306 and the potentiometer 304, the output voltage Vg' from the position sensor 91 appears. In operation, the voltage Vg 'of the terminal R' is equal to the voltage V _DD multiplied by the ratio of the resistance of the potentiometer 304 to the sum of the resistance of the potentiometer 304 and the resistance of the resistor 306. As the carriage 86 moves on the disk 84, the contact 302 moves on the potentiometer 304 to change the resistance value of the potentiometer so that the output voltage Vg 'becomes the output voltage Vg' of FIG. It is used to control the bias current supplied by the bias generator 120. In this way, the bias voltage for the compensator 117 is made to respond to the pickup position on the disk 84. In this manner, by coupling terminal R 'to the input of bias generator 126 in FIG. 2, output voltage Vg' can be used to control the bias voltage for diode 124.

4 shows an example of the bias generator 120 shown in FIG. The MOS device 402 has a supply voltage source V _BB (e.g., a gate 404 connected to the input terminal R to a source 406 through a resistor 410 and a drain 408 through a resistor 412). , A positive voltage source). A bias current is supplied to the bias resistor 122 of FIG. 2 from the terminal T coupled to the connection point of the resistor 412 and the drain 408. During operation, the control voltage Vg is supplied to the terminal R by the position sensor 91 (at the terminal R ') and the servo device 130 (at the terminal R''). When the control voltage Vg changes, the current flowing through the drain of the MOS device 402 changes so that the bias generator supplied to the compensator 117 may be used to change the bias voltage supplied to the diode 124. (I.e., used as bias generator 126 in FIG.

The operation of the servo device 130 of FIG. 2 will be described with reference to FIG. The positive voltage Vp from the output of the peak detector 132 is shown at the input terminal P of the servo device 130. Voltage Vp is applied to the input of voltage comparator 502 through switches A and B. The output of comparator 502 is passed through switch C to the input of JK flip-flop 504. The output of flip-flop 504 passes through resistor 506 and switch D and is coupled to output terminal R " and a ground source.

In operation, A, B, C, and D are closed and opened in ADBC order. At some time t, switch A is closed and then opened, at which time voltage Vp (t) is accumulated in voltage comparator 502. After some time T, switch B is closed and then opened. The voltage at time t + T, ie Vp (t + T), is compared to Vp (t) at comparator 502. At this time, if Vp (t + T) < Vp (t), negative bead is reduced during time T. The output of comparator 502 is low when the negative bead is reduced. Thus, even if switch C is closed and then opened, no pulses are applied to the JK flip-flop, leaving the flip-flop output intact. Here, assume that the output of flip-flop 504 is positive. At this time, the switch D is closed to increase the contact voltage V &quot; of the terminal R &quot; to adjust the bias voltage applied to the hole corrector 117 through the bias generator 120 of FIG.

The voltage Vg &quot; increases until V _D (t + T) &gt; Vp (t), indicating that the bias voltage for the compensator 117 is changed so that the negative bead is increased. At this time, the output of the comparator 502 becomes high so that when the switch C is closed, the output of the flip-flop 504 changes state from the positive output to the negative output. When the switch D is closed, the output voltage Vg &quot; decreases so that the bias voltage for the corrector 117 decreases.

The output voltage Vg '' continues to decrease until the voltage Vp (t + T) becomes greater than Vp (t) again. At this time, the output of the flip-flop 504 changes the state from negative to positive to increase the output voltage Vg ''. In this way, the servo device 130 generates an output voltage Vg &quot; that increases or decreases so that the bias voltage for the compensator 117 is adjusted so that the negative bead is kept to a minimum.

The switches A, B, C, and D of the servo device shown in FIG. 5 may use CMOS devices (not shown) controlled by clock pulses from a clock generator (not shown).

Thus, the servo device described in FIG. 5 can be used as the block 126 in FIG. 2 for changing the bias voltage supplied to the diode 124.

The nonlinear hole correction device described with reference to FIGS. 1 and 2 is effective in removing secondary intermodulation products, but it is not necessarily effective control of products by higher order intermodulation products. In order to perform substantial control of the high-order intermodulation products, a balanced configuration is taken for the nonlinear hole correction apparatus of FIGS. 1 and 2.

In this balanced configuration, the aberration intermodulation products are substantially excluded by installing two nonlinear signal paths. The signal reproduced by the reproducing means is applied to these two nonlinear signal paths. The signal is inverted in the first signal path and the signal is not inverted in the second signal path. Thus, when the signal from the first signal is combined with the signal from the second signal (eg in a linear adder), the odd-order intermodulation product is substantially eliminated.

FIG. 6 shows a preferred embodiment of the nonlinear hole correction device shown in FIG. 2 used to reduce voice interference in video. The circuit element including the compensator 117 between the terminal 202 'and the terminal 204' of FIG. 2 is removed. A terminal 202 coupled to the circuit terminal 202 ′ of FIG. 6 and a terminal 204 coupled to the terminal 204 are connected. Therefore, the output from the pickup circuit 90 of FIG. 1 is supplied to the input terminal 202 of FIG. 6, and the output terminal 204 of the draft 6 is coupled to the image carrier band filter 92 of FIG. Switch 110 is closed and switches 112, 114, and 115 are open.

In FIG. 6, an input terminal 202 is provided in the input circuit 205. As shown in FIG. The voltage divider 206 provided in the input circuit 205 includes resistors R ₁ and R ₂ connected in series. A trap filter 208 composed of an inductor L ₁ and a capacitor C ₁ connected in series is connected in parallel to the resistor R ₂ of the voltage divider 206. In addition, the capacitor C ₂ is connected in parallel with the resistor R ₂ and the trap filter 208 in parallel.

A high pass filter 210 consisting of a capacitor C ₃ and resistors R ₃ and R ₄ is connected to the output of the input circuit 203. The output of the high pass filter 210 is emitter through a small resistor (100 kV). The base electrode of the follower transistor T ₁ is connected.

Current from the four signals (T ₃ and T ₄ form a feedback transistor) is visible at the base of transistor T ₃ . The first signal, which is the main conduction of the video signal, extends from the emitter of emitter follower T ₁ to the base of transistor T ₃ via capacitor C ₄ . The second signal also includes a nonlinear device diode D ₁ and capacitors C ₇ and C ₈ . The second signal is one of two legs of the balanced nonlinear hole correction device.

The PNP transistor T ₂ is included in the third signal path. Diode D ₂ connected to the emitter of inverter transistor T ₂ provides a nonlinear impedance that nonlinearly changes the gain of transistor T ₂ .

The signal path from the emitter of the emitter follower transistor T ₁ to the addition point, ie the base of the transistor T ₃ , via the inverter stage T ₂ becomes the other of the two legs of the balanced nonlinear hole compensator. The fourth signal is provided by the series connection of the capacitor C ₅ and the resistor R ₅ . The fourth signal is provided to compensate for the reverse polarity signal flowing through the emitter electrode of the resistor R ₆ and the transistor T ₂ . If the current source is ideal, this fourth signal path may not be present.

The cathode of the diode D ₂ is connected to the anode of the diode D ₁ through a resistor R _7, the cathode of the diode D ₁ is connected to the movable element of the potentiometer R _8. A bias voltage defines the anode of the diode D ₂ through the resistor R ₆ is applied, and the cathode of the diode D ₂ is grounded through a capacitor C to fall into a signal including _6. The transistor T is between the emitter and cathode of the diode D ₁ of the capacitor C _{1, 7} are connected, and the diode D ₁ of the positive electrode and the transistor T ₃ that is the base gaepeo capacitors C ₈ between the summing point of the connection.

만큼 변위시킨다. 회로(205)에 대한 직선적 전달 특성이 제7a도에 곡선 a로 도시된다.In operation, the output from the pickup circuit 90 of FIG. 1 includes non-linear distortions in which the video output is likely to cause interference due to audio signals on the video output. The nonlinear hole correction device of FIG. 6 serves to substantially eliminate their nonlinearity. The voltage divider circuit 206 connected to the input terminal 202 lowers the level of the input signal so that the signal between the two ends of the two diodes is lower than the peak peak of 100 V, thereby causing each diode to operate at the bend of the response characteristic curvature. do. The voltage divider circuit 206 also provides the resistive power supply impedance of the input circuit 205. The trap filter 208 is configured to remove a control signal of a certain frequency (for example, 260 KHz). Above the resonant frequency of the trap filter 208, the inductor L ₁ becomes a predominant reactance element and resonates at a frequency near the voice carrier in parallel with the capacitor C ₂ . (For example, in a video disc system that includes stereo audio, the audio signal causes low frequency voice carriers to be frequency-modulated over a low frequency deviation range, for example, 715 ± 50KHz and 905 ± 50KHz. is the relative phase of the carrier should, if not controlled gekkeum not obtained the matching of the correct phase, so there is a proper phase of the sound carrier is typically gets obtained capacitor device. capacitor C ₂ lead in the sound carrier frequency described above, circuit 205 Functions as an integrator, circuit 205 provides a 6-decibel octave for all video information, lowers the amplitude of the video and increases the phase of the video carrier.

Displace by. The linear transfer characteristic for circuit 205 is shown by curve a in FIG. 7A.

The high pass filter 210 has a low cutoff frequency (eg, 80 KHz). All low-frequency noise that interferes with the video carrier is removed at this stage.

만큼 위상이 어긋나 있을 경우는 모든 기수차 왜곡이 실질적으로 제거된다.The nonlinear hole correction stage is composed of diodes D ₁ and D ₂ , inverter transistor T _2, and capacitor C ₄ . Diodes D ₁ and D ₂ are separated from each other by resistors R ₇ and capacitors C ₆ , C ₇ and C ₈ with respect to the AC signal. As described above, these diodes connected in series are bias-controlled by one potentiometer R ₈ . The diodes D ₁ and D ₂ have a balanced configuration such that the aberration voice distortion in the video signal is reduced or eliminated with respect to the AC signal. Diodes D ₁ and D ₂ is because it is biased by the same bias current, the transistor through the collector of T ₂ is odd number order distortion of sinhojung sent to the summing point at the of the transistor T ₃ the base is the base of the transistor T ₃ via the diode D ₁ It is balanced against the aberration distortion sent to the addition point. The aberration distortion through diode D ₁ is equal to the aberration distortion through the collector of transistor T ₂ and 180 degrees.

If the phases are shifted by much, all the aberration distortions are substantially removed.

만큼 변위된다. 미분기(즉 캐퍼시터 C₄와 궤환트랜지스터쌍 T₃및 T₄)에 관한 직선적 전달 특성이 제7b도에 곡선 b로 도시된다.At the same time, the distortion of the even difference is substantially eliminated by the modulation effect by the combination of two nonlinear signals into one linear signal. By combining the feedback transistor pairs T ₃ and T ₄ with the capacitor C ₄ , the video signal is differentiated so that the phase of the video signal is approximately 90 degrees.

Is displaced by The linear transfer characteristics for the differentiator (ie capacitor C ₄ and feedback transistor pairs T ₃ and T ₄ ) are shown by curve b in FIG. 7b.

의 위상관계로 한다. 즉 다이오드 D₁과 D₂에 의해 발생되는 상호 변조파에 대해서 90

의 위상관계로 한다. 그 결과 비디오 반송파와 음성 반송파에 의해 위상변조된다. 생성되는 상호변조파의 진폭, 즉 이에 따른 위상변조의 양은 다이오드의 바이어스 전류함수로서 이 다이오드 바이어스 전류함수로서 이 다이오드 바이어스 전류는 다이오드 D₁과 D₂에 있어서의 위상변조가 비선형 재생수단에 의한 위상변조를 실질적으로 상쇄하게끔 조정된다.Considering the signal at the emitter of transistor T ₁ as the reference phase, the nonlinear elements D ₁ and D ₂ have the same polarity through D ₁ for the negative part of the voice carrier and T ₂ for the positive part of the voice carrier. Through the semi-electrode, the video carrier is sent to the addition point (base of transistor T ₃ ). In other words, it may be considered that the nonlinear device generates an intermodulation signal in phase with the emitter signal of the transistor T ₁ . The reactance of capacitor C ₄ is 90% of the main signal at the add point to the main signal at the emitter of the transistor.

Let phase relationship be That is, for the intermodulation wave generated by diodes D ₁ and D ₂ , 90

Let phase relationship be As a result, phase modulation is performed by the video carrier and the voice carrier. The amplitude of the generated intermodulation wave, i.e., the amount of phase modulation, is the bias current function of the diode, which is the diode bias current function, and the diode bias current is the phase modulation of the diodes D ₁ and D ₂ by the nonlinear regeneration means. Adjusted to substantially cancel modulation.

의 위상관계를 갖고서 캐퍼시터 C₄를 통하여 전송된다. 가산점( 트랜지스터 T₃의 베이스)에 있어서의 이들 신호의 조합은 다이오드 D₁과 D₂에 의해 생성된 측파대가 비선형의 재생장치에 의해 원 신호중에 발생된 측파대를 효과적으로 상쇄기키기 때문에 어떠한 실질적인 상호 변조파도 포함하지 않는다.For a description of the operation of the nonlinear hole compensator, consider a signal S (t) with even-order intermodulation products produced by the regeneration means in the emitter of the transistor T ₁ . Diodes D ₁ and D ₂ generate the signal S (t) and the even-order distortion component of the in-phase (ie, the sum of S ² (t) and the higher-order even-order distortion whose amplitude is not too large). In particular, the diode current applies a negative sideband (for example, signals of 5 ± 0.713MHz and 3 ± 0.903MHz) to the video carrier. At the same time, the main video signal is signal S (t) 90 at the emitter of transistor T ₁ .

Are transmitted through capacitor C ₄ with a phase relationship of. The combination of these signals at the addition point (the base of transistor T ₃ ) is not practical because any sidebands generated by diodes D ₁ and D ₂ effectively cancel the sidebands generated in the original signal by the nonlinear reproducing apparatus. It does not include intermodulation waves.

The integration by the circuit 205 compensates for the derivative made in the capacitor C ₄ to provide a nearly flat response characteristic for the nonlinear hole corrector.

The negative travel signal from the pickup circuit 90 shown in FIG. 1 (when the switch 110 is closed) causes phase advance in the non-linear hole correction device of FIG. 2 while the signal of FIG. Note that supplying to the input terminal 202 causes a phase delay in this nonlinear hole correction device. This means that the nonlinear hole compensator depends on the polarity. In the case where the signal output polarity from the pickup circuit 90 shown in FIG. 1 is more negative in the voice portion than in the voice curve portion, it is necessary to configure the hole compensator so that the phase advances as the input signal is more attenuated. have. Conversely, if the polarity of the input signal to the hole compensator is more positive at the top of the voice than at the voice curve, as shown in FIG. It is necessary to configure this to be advanced. It is noted that the nonlinear hole correction circuit can be made by other techniques (as shown in FIG. 6). For example, the integrator may be placed behind the differential rather than before it. However, it is advantageous to arrange the integrating device as shown in FIG. First, the diode is operated on the smooth portion of its nonlinear characteristics, reducing the amplitude of the video carrier. In other words, the diode is not blocked. Secondly, the modulation of voicebits is better controlled. The voice carriers are attenuated by the ratio of R ₁ and R ₂ , and the video carriers are attenuated by the ratio of these resistors times the integral effect of the integrator. As the amplitude of the audio carrier increases with respect to the amplitude of the video carrier, the modulation becomes smaller than the distortion of the video carrier, thereby resulting in greater modulation.

In addition, balanced or unbalanced nonlinear hole compensation devices can be installed in the input circuit and feedback transistor pairs.

It is also possible to configure the particular equilibrium configuration described with reference to FIG. 6 in other ways. For example, the inversion of the balanced signal can be performed after modulation rather than before modulation.

The present invention can be used for any method of generating an interference signal of a system in which an interference signal is generated upon matching of a conversion device and a signal track. Whether the grooved system or the grooveless system used in combination with any of a number of converters can use the present invention.

Claims (1)

A reproducing apparatus having reproducing means 88,90 having nonlinear response characteristics for reproducing an information signal modulated from a disc record medium, the reproducing apparatus being coupled to the reproducing means and reproduced due to the nonlinear response characteristic of the reproducing means. Means for demodulating the non-linear correction means 117 and 124 for reducing the interference caused during the operation, means 96 for demodulating the information signal, and means for processing the demodulated signal, coupled to the demodulation means. A reproducing apparatus, further comprising (100).

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