NL7900584A - Video disc record pick=up for spectral range response correction - has laser beam optical system with prismatic beam splitter to divert light to photodetector connected to amplifier control circuit - Google Patents

Abstract

The video record plate (11) has reflective and non-reflective regions forming circular arc tracks representing 3.58 MHz luminance record signals. These are scanned by an objective lens (31), the light from a laser (23) beam being reflected by a radial minor (29) through a quarter wave plate (27) to a beam splitting prism (25) into a photodetector (21) which measures the intensity of the reflected light. Electrical signals from the photodetector are fed into an electronic circuit which analysis the frequency characteristics so that the intensity of the chrominance burst signal is assessed. This may be converted by a demodulator into an amplitude control signal in order to balance the chrominance signal intensity relative to the luminance signal intensity.

Description

-wf -1- 22427 / JF / sb <Applicant: MCA DISCOVISION, LMC., California, United States of America.

Short designation: Device for correcting variations in the spectral response of a video disc playback system.

5

The invention relates to a device for use in a signal recovery system for recovering a video signal from a video disc.

Video plates are mainly used for storing frequency-modulated video signals encoded in the form of an alternating series of light-reflecting and light-non-reflecting areas arranged in a number of substantially circular information tracks, which are either form a spiral or concentric circular pattern on the plate. Usually each track contains the information for one video image. Conventional video record playback systems operate to recover video signal from the record using an objective lens which focuses a beam of radiation onto the record as it rotates with respect to the beam at a constant angular velocity, thereby generating a reflected beam of radiation at an intensity modulated by the recorded information. This reflected beam is redirected through the projection lens to a photo detector which generates a corresponding electrical signal, which is then frequency demodulated to generate a conventional baseband video signal for conventional processing by a conventional television receiver.

Since the circumference of the information tracks located near the circumference of the plate is substantially larger than that of the tracks near the center of the plate, the dimensions of the successive light-reflecting and light-non-reflecting areas become smaller and smaller as the track radius decreases. Accordingly, the limiting resolution of the objective lens usually becomes a limiting factor in recovering information from the small beam traces, and the high frequency portion of the frequency modulated video signal recovered from such traces is attenuated by an inverse proportion is with the radius of the tracks. The lens thus corresponds to a low-pass filter with a variable bandwidth which is directly proportional to the radius of the track.

7 9 0 0 5 S 4

V

IS

-2- 20427 / JF / sb

A conventional NTSC format video signal includes a baseband luminance signal and a chromination subcarrier placed at 3.58 MHz. Accordingly, most of the lurainance information on a carrier wave that is frequency modulated by such a video signal is placed in a frequency region near the carrier wave, and a substantial portion of the chrominance information is in more distant side bands. When the radius of the track from which information is recovered decreases, the aforementioned low-pass filtering effect of the objective lens causes a weakening of the carrier with frequency-10 region immediately adjacent to it, while the lower sidebands (containing the chrominance information) substantially remains unaffected. Consequently, the amplitude of the chrominance portion of the finished video signal with respect to the luminance portion of the signal will increase as the track beam decreases. Therefore, the video signal recovered from the inner tracks of the record will not have a standard video signal format.

Conventional techniques for equalizing the relative amplitudes of the chrominance and luminance portion of a video signal have necessitated separation of the two signal portions, followed by amplification of one of the two variable amount portions to correct the amplitude variation . This is not a completely satisfactory technique within the current environment, because it requires essentially special circuits which are not otherwise required, thereby increasing both the complexity and the cost of the playback system. Accordingly, there is a need for a device for equalizing the relative amplitudes of the chrominance and luminance portion of the frequency-modulated video signal recovered from the video disc without the need to separate the demodulated video signal.

The object of the invention is to eliminate the above drawbacks and. provides for this purpose an apparatus, characterized in that the signal comprises luminance information, chrominance information and periodic chrominance bursts of a prescribed amplitude, which signal is included in a sequence of light-reflecting and light-non-reflecting regions , which form a plurality of substantially elliptical and concentrically arranged information tracks, and which system comprises means for focusing a beam of radiation on a selected track while the plate rotates with respect to the beam with a prescribed angular velocity and means for detecting a reflected radiation beam with an intensity modulated by the recorded video-5 signal, the amplification factor of the higher frequency portion of the spectral response of the signal recovery system decreasing as the beam of the selected track decreases, with a corresponding vari ation in the respective amplitudes of the chrominance and luminance portion of the recovered video signal is caused to operate the device for correcting the variable gain of the system by controllably amplifying the corresponding portion of the frequency spectrum of the recovered video signal. the apparatus comprising: means for detecting the amplitude of the successive chrominance bursts in the recovered video signal and generating a corresponding control signal; and means for amplifying the video signal recovered from the record, which control signal is coupled to the amplifying means for controllably adjusting the gain therefor over a frequency band corresponding to the higher frequency portion of the recovered video signal, thereby becoming the variable gain of the signal recovery system corrected.

In principle, the invention is embodied in an apparatus for use in a video disc playback system which recovers a video signal from a rotatable video disc. The apparatus works to correct for variations in the relative amplitude of the luminance and chrominance portions of the reproduced video signal caused by spectral limitations of the playback system, such as the limiting resolution of an objective lens. According to the invention, the apparatus comprises means for detecting the amplitude of the successive chrominance bursts in the recovered video signal and for generating a corresponding control signal together with means responsive to the control signal or for controllably adjusting the amplitude of the reproduced signal in a prescribed frequency range. Accordingly, the respective amplitudes of the luminance and chrominance portion of the reproduced video signal can be maintained at their proper mutual levels, such as 7900534.

-4- 20427 / JF / sb.

the need to separate the respective signal portions, thereby substantially reducing the complexity and cost of the device.

The video signal recorded on the plate can be frequency modulated on a carrier of around 8 MHz. Since a conventional NTSC format video signal includes a baseband luminance signal and a chrominance subcarrier signal centered at 3.58 MHz, the frequency-modulated video carrier will have most of the luminance information in the frequency region near the carrier and a substantial portion of the chromi -10 nancy information on more distant sidebands, with the first order sideband being 3.58 MHz below the carrier frequency.

In accordance with a more detailed aspect of the invention, the means for adjusting the relative amplitudes of the luminance and chrominance portion of the video signal comprises a frequency-selective variable gain amplifier tuned to approximately the carrier frequency, at a ratio of center frequency to bandwidth of the variable gain factor amplifier (i.e. "Q") which is controllably adjusted by the control signal. When the amplitude of the successive chrominance bursts is relatively low, indicating that the video signal is recovered from the tracks near the periphery of the plate, the control signal causes the amplifier to have a relatively lower Q, amplifying a wide frequency band. Conversely, when the amplitude of a burst is relatively high, indicating that the signal recovered from the tracks is near the center of the plate 25, the amplifier stage automatically has a relatively larger Q, with the frequency band in the immediate vicinity of the modulated carrier is amplified by a larger amount. Thus, when small beam traces are read, the luminance portion of the modulated video signal will be amplified by a greater amount than the chrominance portion, thereby compensating for limited spectral response of the objective lens.

The frequency-selective variable gain factor amplifier preferably includes an RLC tank circuit, in which the parallel resistance is varied in accordance with the control signal. Application of the control signal to a forward switched diode is one effective technique for providing such a variable resistor.

The means for detecting the amplitude of the corresponding chrominance bursts in the recovered video signal comprises, in one embodiment, a narrow band-pass filter centered at 3> 58 MHz when separating a portion of the chrominance subcarrier from the frequency-demodulated video signal. The filter only needs a bandwidth sufficient to transmit a large portion of the successive chrominance bursts, with the remaining portion of the chrominance signal unnecessary.

In accordance with another aspect of the invention, the amplitude detection means may comprise means for allowing manual adjustment of the Q of the frequency selective variable gain factor amplifiers. This can be accomplished using a potentiometer connected to generate a variable voltage which is added to the aforementioned control signal and coupled to the variable gain factor amplifier. This allows manual compensation for variations in the characteristics of the video disc playback system, in particular the objective lens, and for tolerances of the components of the circuit.

Other aspects and advantages of the invention will become apparent from the following description of a preferred embodiment in conjunction with the drawing, in which: Fig. 1 is a simplified schematic of a video disc playback system. 25 for reproducing a frequency-modulated video signal which can be processed by the device according to the invention; Fig. 1a is an enlarged detail of the video disc near the periphery. Fig. 1b is an enlarged detail of a portion of the video disc near the center of the disc; FIG. 2 is a block diagram of an apparatus according to the invention for correcting any variation in the relative amplitudes of the luminance and chrominance portion of the video signal reproduced by the playback system of FIG. 1; Figure 3a is a graph of the frequency spectrum of the FM video-35 signal recorded on the video plate of Figure 1; 7900584-6u227 / JF / sb β Fig. 3b is a graph of the spectral response of the objective lens of the playback system of Fig. 1 showing the increased attenuation of higher frequencies as the scanned track radius decreases; FIG. 3c is a schematic of the spectral response of the FM-5 signal amplification circuit of FIG. 2, which shows a larger high frequency gain when decreasing the radius of the track being scanned; and FIG. H is a schematic of the frequency selectively variable gain factor amplifier of the FM signal amplification circuits of FIG. 2.

In Fig. 1 of the drawing, a video disc playback system is shown for recovering a frequency-modulated video signal from a rotatable video disc 11. The reproduced video signal is applied to an fm signal correction device (Fig. 2), which operates to correct for variations in the relative amplitude of the luminance and chrominance portion of a signal caused by spectral limitations of the playback system.

The frequency-modulated video signal is stored on the video disc 11 in an alternating series of light-reflecting and light-non-reflecting regions 13 and 15, which form a number of substantially circular information tracks 17 arranged in either a spiral or a concentric circular pattern on the plate. Each information track contains information for one total video image. As shown in Fig. 3a, the signal comprises a carrier of around 8 MHz which is frequency modulated by a conventional NTSC signal with a baseband luminance section and 3.58 MHz chrominance sub-carrier section. Since the luminance portion of the modulating video signal generally occupies a lower frequency band than the chrominance portion, most of the luminance information in the fm signal is located in the frequency range immediately adjacent to the 8 MHz carrier. part of the chrominance information is visible in the more distant side bands. In particular, most of the chrominance information is in the first order lower sideband 18, 3.58 MHz below the carrier.

The video disc playback system (Fig. 1) operates to recover the FM video signal information by resetting a read batch 7900534 • c -7- 20427 / JF / sb del 19 on a selected information track 17 on the video disc 11 while the plate rotates with respect to beam at a prescribed ... constant angular velocity. A reflected radiation beam 19 'is thereby generated, with an intensity modulated by the pattern of light-reflecting and light-non-reflecting regions 13 and 15 on the selected information track. This reflected beam is returned to a photo detector 21 to detect the modulated information. The radiation beam 19 is generated by a laser 23 and transmitted through a beam splitting prism 25 and a quarter-wave plate 27, after which it is reflected by a radial track mirror gel 29 and focused on the plate 11 by a microscope objective lens 31. A radiation spot 33 is formed at the point of incidence of the beam on the plate with a diameter of the dot, which is a function of the resolving power of the lens, which is approximately equal to the width of each information track 17 · The opening of the objective lens 31 it is preferably fully illuminated by the radiation beam, so that the resolving power of the lens is fully utilized. The beam 19 'reflected from the plate essentially traces the same optical path back to the beam splitting prism 25, where it is reflected by the photo detector 21 to sense its modulated intensity.

Figures 1a and 1b show an enlarged and simplified form of the arrangement of alternating light-reflecting and light-non-reflecting regions 13 and 15 for a portion of the video disc 11, respectively. near its perimeter and near its center. It will be noted that the distance between adjacent tracks remains constant across the plate 25, but the length of the successive light-reflecting and light-non-reflecting areas are substantially smaller for tracks near the center of the plate with respect to the tracks near the outline of the plate. As noted above, the size of the radiation spot 33 is roughly equal to the width of each information track. Thus, when the beam of the information track being scanned decreases, and thus the length of the successive light-reflecting and light-non-reflecting areas approaches the size of the radiation spot, the modulated intensity of the reflected beam 19 'will not more so sharply defined and the high-frequency portion of the recorded video signal will thus not be so easily detected by the photo detector 21. That is to say, that 7900584 -8- 20427 / JF / sb .- ¾ β · the resolving power of the objective lens 31 becomes a limiting factor in the recovery of the video signal which has an effect on which is generally similar to that of a low pass filter.

As shown in Fig. 3b, the spectral response of the objective lens 31 when scanning the information track 17 near the periphery of the plate 11 is substantially uniform as indicated at 35, while its spectral response when scanning a track near the center of the record has a substantial frequency drop, as indicated at 37 · For intermediate beam information tracks, 10 the degree of frequency drop will be reduced proportionately.

When information tracks 17 near the center of the video disc 11 are scanned by the playback system, the objective lens 31 acts to limit the bandwidth of the reproduced signal by a relatively large amount, attenuating the portion of the signal near the carrier mainly with regard to the lower sidebands. Therefore, not only is the signal to noise ratio of the demodulated video signal reduced, but the amplitude of the demodulated chrominance signal is also increased with respect to the amplitude of the demodulated luminance signal. In addition, the amplitude of the successive chrominance bursts in the demodulator the signal is inversely proportional to the amount of tooth boundary caused by the objective lens.

The FM signal correction device (Fig. 2) operates to correct the aforementioned variable spectral drop-off characteristics of the objective lens 31, correcting the frequency spectrum of the reproduced video signal to more appropriately match that of the actual signal. included. According to the invention, the apparatus comprises gain factor control signal circuits 39 for detecting the amplitude of the successive chrominance bursts in the recovered video signal and for generating a corresponding gain factor control signal, together with the FM signal or gain circuits 41. , which respond to the gain factor control signal, for controllably adjusting the amplitude of the reproduced FM signal in the region near the FM carrier, where the signal is subject to attenuation by the limited resolution of the objective lens 31 · 7900584-9 20427 / JF / ab

As shown in Fig. 3c, the spectral response of the FM signal amplification circuits 41 is variable in accordance with the radius of the selected information track 17, from which the signal is recovered. When a track is scanned near the periphery of the plate 11, a substantially uniform gain is provided for all parts of the frequency spectrum of the FM video signal (Fig. 3a), as indicated at 43- On the other hand, when a track near the center of the disc has been scanned, provides a substantially greater gain for portions of the frequency-10 spectrum attenuated by the objective lens, as indicated at 45. Consequently, the frequency response of the optical portion of the video disc playback system is in combination with the FM signal amplification circuit 41 is substantially uniform across the entire frequency spectrum of the video signal, regardless of the radius of the information track 15 from which the signal is recovered.

As shown in Fig. 2, the FM signal amplification circuits 41 include an amplifier 47, a frequency-selective variable gain factor amplifier 49, and a low pass filter 51. The uncorrected FM video signal is provided over line 55 of the photo detector 21. (Fig. 1) 20 is first amplified in the amplifier 47, after which it is fed over line 57 to the variable amplification amplifier 49, which adjusts the amplitude of the signal in the frequency range where it is attenuated by the objective lens 31 in accordance with the gain factor control signal, as described above. The signal generated by the variable gain factor amplifier 49 is sent on line 59 to the low pass filter 51, which limits its bandwidth to about 12-12MHz. The filtered signal, in turn, is transferred over line 61 to a limiter 62 to remove substantially all amplitude variations of the signal, thereby generating a corrected FM video signal.

The corrected FM video signal, which substantially corresponds to the video signal recorded on the plate 11, but with the upper side bands removed, is fed over line 63 from the limiter 62 to a frequency demodulation circuit 65, which demodulates the signal to the base band. The baseband signal is applied in its turn over line 7900534 3 -10- 20427 / JF / sb 67 to the gain factor control signal circuits 37, which process the signal and generate the gain factor control signal for coupling to the FM signal gain circuit 41. In addition, the baseband video signal is applied to other subsystems of the video disc playback system such as, for example, a time base error correction system (not shown) before a carrier amplitude is modulated and connected to a conventional television receiver.

The gain factor control signal circuits 39 include a 3.58 MHz band-pass filter 69, an amplitude detector 71, a sample-10 sample and hold circuit 63, a summing amplifier 75, a low-pass filter 77. The band-pass filter 69 which receives the base band video signal over line 67 of the frequency demodulator 65 has a bandwidth which is approximately limited to 100 KHz, substantially all of the successive chrominance bursts being transmitted while filtering out a substantial portion of the remainder of the chrominance signal and most of the luminance signal. The filtered chrominance bursts are then transferred via line 79 to the amplitude detector 71, which operates to generate analog voltage signal proportional to the peak amplitude of the filtered signal.

The analog voltage signal is transferred via line 81 from the amplitude detector 71 to the sample and hold circuit 73, which, under the control of a conventional burst gate signal, samples the analog voltage signal each time it matches one of the. successive chrominance bursts. The burst gate signal commonly generated in synchronization circuits (not shown) located elsewhere in the video disc playback system is supplied to the sample and hold circuit 73 on line 83. In addition, the sample and hold circuit includes suitable inversion and level shift circuits. , the output being a maximum positive voltage when 30 low amplitude chrominance bursts are detected. (I.e., when outer tracks are scanned), and the output is a voltage near zero when relatively high amplitude bursts are detected (i.e., when inner tracks are scanned).

The signal generated by the output of the sample and hold circuits 73 is coupled via line 85 to the summing amplifier 72 and in turn at 7900584-112027 / JF / sb via line 87 to the low pass fliter 77, which pre-amplification gain control signal generated for transmission over line 89 to the frequency-selective variable gain amplifier 49 of the FM signal amplification circuit 41. The low pass filter 77 has a bandwidth of around 1 KHz and acts primarily to reduce transition effects. which would otherwise result from the stepped voltage changes generated in the sample and hold circuit 73.

Thus, it will be appreciated that a feedback control system 10 is thereby formed to stabilize the relative amplitude of the successive chrominance bursts in the demodulated video signal. When information tracks on the periphery of the plate 11 are scanned, the amplitude of the successive chrominance bursts relative to that of the luminance signal is essentially corrected, and the control signal is therefore at a maximum level. This causes the variable gain factor amplifier 49 to have a low Q and thus amplify the entire frequency spectrum of the FM signal. When reverse traces of information are scanned near the center of the plate, the successive chrominance bursts are found to have an amplitude too great with respect to that of the luminance signal, and the control signal is then at a minimum level. This causes the variable gain factor amplifier to have a relatively high Q, amplifying the portion of the signal spectrum near the FM carrier by a greater amount around the rest of the signal spectrum. A substantially uniform relationship between the amplitude of the respective luminance and chrominance signals will therefore result, regardless of the radius of the information track 17, from where the signal is recovered.

In addition, the gain factor control signal circuits 39 may include a potentiometer 91 for making a setting of the nominal Q for the frequency-selective variable gain amplifier 49 manually. In one embodiment, the potentiometer is suitably connected to generate a variable positive voltage, which is coupled via line 93 to the summing amplifier 75, where it is added to the voltage signals generated by the sample and hold circuit 73. This manual gain factor setting property allows for compensation for variations in the gain factor characteristics of the video disc playback system, in particular for the objective lens 31 as well as circuit component tolerances.

FIG. 4 shows a preferred embodiment for the frequency selective variable gain amplifier 49 of the FM echo recorder. The circuit includes an n-channel FET 95 in combination with an RLC tank circuit 97 and a forward switched diode 99 coupled to the drinking terminal of the FET. The FET is set in a conventional manner with the "source and gate" terminals connected to ground through resistors 101 and 103. The FM video signal input which is supplied on line 57 by the amplifier 47 is AC voltage coupled to the FET gate clamp through a capacitor 105.

The source terminal of the FET is the output of the variable gain 15 factor amplifier for transfer on line 59 to a low pass filter 61.

The RLC tank circuit 97 includes a parallel connected resistor 107, coil 109, and capacitor 111, one of the tank circuit is connected to a positive supply voltage supply voltage + V and the other side forms a node 113 which is coupled to the straining terminal of the FET via resistor 115. The tank circuit is tuned to the frequency slightly above the carrier frequency and the parallel resistor 107 is chosen to provide the highest Q ever desired (i.e. when information tracks 17 after -25 at the center of the plate 11 are scanned). The diode 99 is directed in its cathode connected to ground and its anode connected through a series resistor 117 and capacitor 119 to the tank circuit zero 113. In addition, the gain factor control signal supplied on line 89 through the low pass filter 77 is connected to the 30 anode of the diode via a resistor 121.

Thus, when the gain factor control signal is applied to the variable gain factor circuit 49, a predetermined current will flow through the diode 99 and the resulting AC voltage resistance of the diode together with the resistor 117 will effectively cut the tuned circuit resistor 107. This has the effect of 7900584-132027 / JF / sb changing the Q of the tuned circuit 97 and thereby varying the bandwidth of the frequency range in which a relatively high gain is provided. When the control signal has a relatively low voltage, the AC voltage resistance of the diode 99 will be relatively high and a relatively high Q will result, thereby amplifying a narrow band of frequencies centered on the resonant frequency by a larger amount. Conversely, when the control signal has a relatively high voltage level, the AC resistance of the diode will be relatively low and a relatively low Q10 will result, amplifying a wider range of frequencies.

From the foregoing description, it is to be understood that the invention provides an effective apparatus for correcting the boundaries of the spectral response of the objective lens of the video-record playback system, wherein the relative amplitudes of the chrominance and luminance portions of the video signal recovered from the plate are kept substantially constant regardless of the radius of the information track from where the signal is recovered. In addition, this relative amplitude control is achieved without the need to separate the luminance and chrominance portion of the video signal.

Although the invention has been described in detail with reference to a presently preferred embodiment, it will be understood by a person skilled in the art that various changes can be made without departing from the spirit and scope of the invention.

-Conclusions- 7000534 • -

Claims (9)

Device for use in a signal recovery system for recovering a video signal from a video disc, characterized in that the signal comprises luminance information, chrominance information and periodic chrominational bursts with prescribed amplitude, which signal is contained in a sequence of light-reflecting and light-non-reflecting regions, which form a number of substantially circular and concentrically arranged information tracks, and which system comprises means for focusing a radiation beam on a selected track while the plate 10 rotates with respect to the beam at a prescribed angular velocity and means for detecting a reflected radiation beam with an intensity modulated by the recorded video signal, the gain of the higher frequency portion of the spectral response of the signal recovery system decreasing when 15 the radius of the g Selected track decreases, causing a corresponding variation in the respective amplitudes of the chrominance and luminance portion of the recovered video signal to operate the device for correcting the variable gain of the system by controllably amplifying the corresponding part of the frequency spectrum of the recovered video signal, the device comprising: means for detecting the amplitude of the successive chrominance bursts in the recovered video signal and generating a corresponding control signal; and means for amplifying the video signal recovered from the record, the control signal 25 being coupled to the amplifying means for controllably adjusting the gain therefor over a frequency band corresponding to the higher frequency portion of the recovered video signal, thereby varying the variable gain of the signal recovery system is corrected. Device according to claim 1, characterized in that the video signal recorded on the plate contains a carrier wave, which is frequency-modulated by a baseband luminance signal and a chrominance subcarrier, with a substantially larger proportion of chrominance information than luminance information in the modulated signal is placed in spaced lower sidebands; and wherein the amplitude of the chrominance information 7910584-152027 / JF / sb in the reproduced frequency modulated video signal varies inversely with the radius of the selected track. 3. Device according to claim 2, characterized in that the relative lengths of the successive light-reflecting and light-non-reflecting regions, each of which forms a number of information tracks, are substantially directly proportional to the radius of the corresponding track ; and in that the radiation beam focusing means comprises an objective lens having a limited resolving power which acts to reduce the spectral response of the signal recovery system when the relative dimensions of the light-reflecting and light-non-reflecting areas decrease. 4. Device as claimed in claim 1, characterized in that the amplifying means comprise an amplifier with a variable amplification factor which is tuned to the higher frequency part of the video signal spectrum, of which amplifier the Q is controllable by the control signal. 5. Device according to claim 4, characterized in that the variable gain amplifier comprises a tank circuit with a resistor element of a magnitude controllably adjustable by the control signal. Device according to claim 5, characterized in that the resistor element comprises a forward-switched diode to which the control signal is applied. 7. Device according to claim 1, characterized in that the device further comprises means for enabling manual adjustment of the amplification factor of the amplification means in the region of the higher frequency portion of the signal spectrum. 8. Device according to claim 1, characterized in that the amplitude de-deflection means comprise a narrow bandpass filter which is tuned to the frequency of the chrominarition subcarrier, which filter has a bandwidth selected for transmitting in substantially the total portion of each of the successive chrominational bursts, but attenuating a substantial portion of the remainder of the chrominformation information and attenuating substantially all of the luminance information. Device according to claim 8, characterized in that the band-pass filter has a bandwidth of less than 100 KHz. 79 0 0 5 8 4 *****