DE3048544A1 - VERTICAL CORRECTION CIRCUIT - Google Patents

Description

30485A4

The invention relates to a vertical aperture correction circuit for a color image pick-up device / for changes in the brightness level of the video image from one line interval to the next and reduce the line crawl effect of the video signal.

In the case of a television picture produced by a color television camera, the so-called edge definition of the picture is not as good as that of a picture from a black and white television camera. This means that a brightness transition or a contrast from one horizontal line interval to the next does not have the desired level of sharpness. A viewer cannot therefore precisely perceive a detail in the vertical direction. This loss of sharpness in the vertical direction, ¹ ie perpendicular to the line scanning direction, is analogous to an aperture error in an optical system.

Various proposals have been made to improve this sharpness. Such correction systems are becoming general referred to as vertical aperture correction systems. With such a typical correction system, the luminance signal, the television signal produced by a black and white television camera or the luminance component of a composite television signal of a color television camera is delayed by one horizontal scan interval, and the The difference between the delayed and the undelayed luminance signal is then generated. When the luminance level is approximately the same in successive line intervals, the aforementioned difference signal has a relative low amplitude. If the brightness level changes from one line interval to the next, this difference can grow. The difference signal can therefore be considered relative accurate display of brightness changes in the vertical direction can be used »

To increase these brightness level changes in the vertical direction, i.e. to obtain a vertical aperture correction,

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a certain part of the difference signal becomes the original, i.e. instantaneous luminance signal added. The sum signal is thus a luminance signal corrected for vertical aperture.

The aforementioned vertical aperture correction technique is accompanied by undesirable disturbance when used in a Trinicon color television camera is applied. In the Trinicon camera, the storage disk of the image pickup tube has one Set of switching electrodes. Obtain these reversible electrodes a switching signal whose polarity is reversed every horizontal scanning interval, so that a switching switching signal is superimposed on the photoconductive storage plate. This switching signal appears to be periodically fluctuating Voltage level that is superimposed on the luminance signal of the Trinicon camera. If the aforementioned correction technique is applied to this luminance signal, the superimposed periodically fluctuating level is raised. Additionally to produce an indication of the changes in brightness level from one line interval to the next is that corrected luminance signal thus provided with a raised superimposed periodically fluctuating level, the leads to the line crawl effect in the reproduced video image.

In addition to this periodically fluctuating level, which is derived from the switching signal, a further AC voltage component due to the operation of a DC-DC converter incorporated in the television camera is used. The DC / DC converter is in the camera provided to generate various DC voltage control signals from a single DC voltage. During normal In operation, the converter is supplied with relatively high voltages, and it is known that thereby an alternating voltage component is caused in the relatively low luminance signal. Such a DC component can be used as an interference signal, typically as a striped pattern, in

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appear on the TV picture being played back. To this disorder To reduce the drive frequency of the DC / DC converter can be synchronized with half the horizontal scanning frequency will. This is exactly the frequency of the switching signal that corresponds to the superimposed periodically fluctuating level of the Luminance signal leads. Therefore, when the correction technique explained above is applied, the DC component of the DC-DC converter results in the aforementioned Line crawl effect.

A technique proposed for eliminating the line crawl effect due to the superimposed switching signal and which eliminates the line crawl effect due to the DC component of the DC / DC converter is disclosed in US Pat 4 160 265 brushed. The difference between the delayed and the undelayed luminance signal, which indicates the changes in the brightness level from line to line and the periodic fluctuations superimposed on the luminance signal are also increased, squared, and the squared difference signal is then mixed with the sum of the delayed and the undelayed video signal. The output of the mixer is a vertically aperture-corrected luminance signal that is essentially dependent on the undesired periodic level fluctuations is free, which is based on the superimposed switching signal of the Trinicon camera or the AC voltage component of the DC voltage converter are due.

The invention is based on the object of creating a vertical aperture correction circuit for a color television camera, which substantially eliminates periodic fluctuations in the amplitude of the video signal and for a color image pickup device is suitable, which generates a video signal with a superimposed periodically fluctuating switching signal that the through the superimposed signal eliminates line crawling effect, and which has a simple structure.

Solutions and expedient embodiments of the invention emerge from the claims.

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In the proposed correction circuit, the line crawl effect is eliminated / without the aforementioned signal quadrature is required.

The invention is explained below with reference to FIGS. 1 to 6. It shows:

FIGS. 1A to 1D signal curves for explaining the mode of operation the correction circle,

Figure 2A to 2D signal curves for explaining the mode of operation of the correction circuit of an image recording device, which superimposes a periodically fluctuating switching signal on the video signal,

Figure 3 is a block diagram of an embodiment of the correction circuit,

FIGS. 4A to 4G show signal curves for explaining the mode of operation of the embodiment in FIG. 3,

FIG. 5 shows a block diagram of a further embodiment and

FIGS. 6A to 6H show signal curves for explaining the mode of operation of the embodiment in FIG. 5.

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The diagrams of FIGS. 1A to 1D show typical signal curves, which are generated by a vertical aperture correction circle / through which the vertical sharpness of the video image is improved. 1A shows the luminance signal Ea, the amplitude of which is a function of the brightness of the video scene is. For the sake of simplicity, the luminance signal Ea is at a constant brightness level with two transitions shown. Fig. 1B shows a delayed signal Eb- des Luminance signal. The delayed luminance signal Eb is opposite by one horizontal scanning or line interval the luminance signal Ea delayed. The difference between the undelayed signal Ea and the delayed one Signal Eb is shown in Fig. Ic as a difference signal Ec. The course of FIG. 1C shows changes in brightness level in the luminance signal from one line to the other. A certain part of the difference signal Ec (Fig. 1C) becomes are added to the original undelayed video signal Ea, and the summed signals are shown as aperture-corrected in FIG. 1D Luminance signals Ey shown. The difference signal Ec can be supplied to an adding circuit through a voltage divider which is the difference signal with a certain division ratio o (divides. The luminance signal · Ey can therefore be represented as Ey - Ea + o (Ec.

The waveforms of FIGS. 2A through 2D show the manner in which a typical vertical aperture correction circle with a Trinicon color television camera is working. The Trinicon camera is described in U.S. Patent No. 3,784,737 and has a storage disk and a set of alternating electrodes supplied with different DC voltage levels that are synchronous can be changed with the horizontal scan rate. There will therefore be a fluctuating signal on the photoconductive disk generates the luminance signal a fluctuating switching signal with a frequency equal to half the horizontal scanning rate superimposed. The luminance signal with the periodically fluctuating level superimposed is shown in FIG. 2A shown as luminance signal Ea. This luminance signal

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is again delayed by one horizontal scanning period in the vertical aperture correction circuit as before; that delayed Luminance signal is shown in Fig. 2B as a delayed signal Eb. The delayed signal Eb is different from the original instantaneous luminance signal Ea subtracted, so that the difference signal Ec in Fig. 2C results. The difference signal Ec is shown with fluctuation levels highlighted. When this difference signal Ec to the original Luminance signal Ea is added, the corrected luminance signal Ey of FIG. 2D results. The corrected A periodically fluctuating signal is superimposed on the luminance signal, which is derived from the switching signal, that has been superimposed on the camera's photoconductive disk. The level of this superimposed fluctuating signal changes with each successive horizontal scanning interval, so that the line crawl effect in the video image which will be played back later. The periodic change in the brightness level of the luminance signal Ey (Fig. 2D) is therefore perceived as a line crawl.

The previous disadvantages, in particular the superimposed fluctuating level of the vertical aperture-corrected Luminance signals are avoided by the invention, an embodiment of which FIG. 3 shows. A video signal processing circuit is connected to a Trinicon color television camera and produces a corrected video output signal, which is essentially free of periodic fluctuations which occur in the amplitude of the video signal from the camera 1. The camera 1 can be constructed like the color image pickup device of the aforementioned US Pat. No. 3,784,737, so that the camera can derive a luminance signal Ea from the mixed color video signal. The luminance signal Ea is from a Video amplifier 2 is amplified and then fed to the video signal processing circuit of the invention.

The processing circuit acts as a vertical aperture correction circuit and consists of a delay element 11, a Subtractor 12, a double limiter 21, an amplitude

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sieve 24 and a mixer 3. The delay element 11 can be a conventional delay element which delays the supplied video signal by one horizontal scanning interval. The delay element 11 is connected to the output of the amplifier 2 and receives the luminance signal Ea. The output of the delay element is connected to the subtracter 12, in which the delayed video signal Eb from original instantaneous luminance signal Ea is subtracted. The output of the subtracter 12 is with the double limiter 21 and the amplitude filter 24 connected. The double limiter receives certain threshold values from a device not shown and allows only those parts of the supplied video signal through which are between the threshold values lie. The threshold values are preferably the same and have opposite levels + L and -L on opposite ones Sides of the mean value of the difference signal of the subtracter 12. When the output of the subtracter 12 is a positive (or negative) signal, the slicer 21 can have a positive (or negative) threshold value fed / so that it only contains the positive (or negative) parts of the output of the subtracter passes that are below the threshold. The output of the slicer 21, i. E. the part of the difference signal, which comes from the subtracter 12 and is below the respective threshold values is from an inverter vice versa and fed to the mixer 3 via an amplitude adjustment circuit 23. The setting circuit is a setting resistor like a potentiometer and can be adjusted so that the mixer 3 has a certain part of the reverse Output signal of the limiter 21 is supplied. By suitably setting the setting circle 2 3 you can this part ß can be changed in the desired manner.

The amplitude filter 24 can pass that part of the difference signal Ec which exceeds a threshold value. If the Threshold values + L and -L are fed to the limiter 21, the same levels can be fed to the amplitude filter 24 so that it passes through the parts of the difference signal Ec

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leaves that exceed the thresholds + L and -L. An amplitude adjustment circuit 25, which is similar to the adjustment circuit 23 can be, feeds the output signal of the amplitude filter 24 to the mixer 3. The setting circuit 25 is used to Set part of the limiter output signal that is fed to the mixer.

The mixer 3 receives the luminance signal Ea, a certain part of the inverted output signal of the limiter 21 and a certain part of the output signal of the amplitude filter 24. The mixer 3 can act as an adder to to add the signals supplied in each case. The output of the mixer 3 is an output terminal as Vertical aperture corrected luminance signal Ey supplied.

The function of the inverter 22 is to divide the output of the limiter 21 from the sum of the video signal Ea and the output of the amplitude filter 24 to subtract. If necessary, the inverter 22 can be omitted, and the mixer 3 may consist of devices which carry out the aforementioned adding and subtracting operations. The luminance signal Ea can, for example, be added to the output signal of the limiter 24 in an adder and the output signal of the amplitude filter 24 can then be subtracted from the added signals in an additional subtracter will.

The operation of the vertical aperture correction circuit of FIG. 3 will now be described with reference to FIGS. 4A to 4G. That FIG. 4A shows the luminance signal Ea of the camera 1. The periodically changing index signal is the brightness level of the luminance signal superimposed. Fig. 4B shows the luminance signal delayed by one horizontal scanning interval. The delayed luminance signal Eb is obtained at the output of the delay element 11.

The subtracter 12 subtracts the delayed luminance signal Eb from the non-delayed luminance signal Ea

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to generate the difference signal Ec of Fig. 4C. The difference signal Ec shows the changes in the brightness of the luminance signal from one horizontal line interval to next and also amplifies the periodically changing level of the luminance signal. The difference signal Ec with the increased brightness changes and periodically changing levels is the double limiter 21 and also the Amplitude sieve 24 supplied.

Fig. 4C shows the thresholds + L and -L used as threshold reference voltages are fed to the limiter and sieve, in broken lines. The levels are + L and -L e.g., equal and opposite levels on opposite sides of the mean level of the difference signal Ec. The limiter 21 passes the part of the difference signal Ec which is between the levels + L and -L. This part of the Difference signal which passes through the limiter 21 / is shown in Fig. 4D as signal Ed and is in mixer 3 for Luminance signal Ea added. This gives the same effect as subtracting the output Ed of the limiter 21 (the amplitude of which is appropriately set) from the luminance signal. Fig. 4E shows a Signal Ee that would be generated if the output signal Ed of limiter 21 were subtracted from the luminance signal Ea would be. 4E shows a waveform generated by the operation Ee = -Ea-Ed. The part of the output signal Ed of the limiter 21, which is fed to the mixer, is determined by the amplitude adjustment circuit 23 is determined so that the periodic changes in Fig. 4D are attenuated and substantially equal to the periodic changes Are changes superimposed on the luminance signal Ea (Fig. 4A). As FIG. 4E shows, the signal has Ee, which is obtained by subtracting the output signal Ed of the limiter 21, the amplitude of which is set, from the luminance signal Ea would be generated, essentially no periodic amplitude changes.

The amplitude filter 24 can also set the threshold values + L

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and -L received. The amplitude sieve leaves the positive and negative part of the difference signal Ec through which the Exceed threshold value + L or -L. The output signal Ef of the amplitude filter 24 is shown in FIG. 4F. The output signal Ef is added to signal Ee (FIG. 4E) after suitable amplitude adjustment by the adjustment circuit 25. That added signal Ey = Ee + Ef, shown in FIG. 4G and is supplied to the output terminal 4 from the mixer 3. That corrected Luminance signal Ey of mixer 3 can be represented mathematically as Ey = Ea - Ed + Ef. That corrected Luminance signal has amplified changes in the brightness level, i.e. the changes in the brightness level from one Line interval are amplified to the next, but that there are periodic amplitude fluctuations of the luminance signal Ea is essentially free. A comparison of the waveforms of FIGS. 4G and 2D shows the improvement achieved. The aperture-corrected luminance signal Ey (FIG. 4G) thus does not have the undesired line crawl effect of the video image finally reproduced therefrom.

The difference signal Ec (FIG. 4C) is processed further before it is mixed with the luminance signal Ea. For however, this further processing has the corrected luminance signal in the form of FIG. 2D. When the difference signal Ec is used directly as the vertical aperture correction signal, the "corrected" luminance signal would be have increased brightness level changes and also contain increased fluctuation levels as shown in Fig. 2D. According to the embodiment of FIG. 3, however, is the same the corrected luminance signal Ey (Fig. 4G) stronger than the corrected luminance signal in Fig. 1D, that of a color television camera that does not superimpose a periodically fluctuating level on the video signal.

The limiter 21 can receive a single threshold value + L and pass the absolute value of the difference signal Ec, which is smaller than this threshold value. Similarly, the amplitude filter 24 can have a single threshold value + L

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and let through the absolute value of the difference signal Ec / which exceeds this threshold value.

The respective settings of the amplitude adjustment circuits 23 and 25 are assumed to be different. The setting circle 23 serves to attenuate the level of the supplied signal by a factor β, and the setting circuit 25 to attenuate the supplied signal by the factor ^. The attenuation ratio β serves to eliminate the fluctuating level of the luminance signal Ea, and the attenuation ratio y in addition, the desired increase in the brightness level changes to reach.

The embodiment of Fig. 3 is a relatively simplified version, a more practical version is shown in Fig. 5, in which the same reference numerals denote the same components. The embodiment of FIG. 5 differs from that of FIG. in that an additional delay element 13 in series is connected to the delay element 11. The output signal of the delay element 13 is in an adder 14 added to the luminance signal Ea. The added signal Eh of the adder 14 is in a subtracter 15 from the delayed Luminance signal Eb at the output of the delay element 11 is subtracted. In the embodiment of FIG the delay elements 11 and 13 cause a delay equal to a horizontal line interval. The luminance signal Ea can also be sent to the subtracter 15 from the delay element 11 and the adder 14 as shown, fed directly are, as well as this adder via a further, not shown delay element, which is used to delay to effect two horizontal line intervals. In this modified embodiment, the delay element 13 can be omitted, and the output of the delay element 11 is only connected to the subtracter 15 (and also to the mixer 3).

The luminance signal Ea appears as in Fig. 6A. This Luminance signal becomes equal to a first delay

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Horizontal line interval from the delay element 11 subjected, so that the delayed luminance signal Eb of Fig. 6B results. The delayed video signal Eb is the delay element 13 by a further horizontal line interval delayed / so that a luminance signal Eg delayed by 2H results, which is shown in FIG. 6C. As previously mentioned, the 2H delay can also be generated in a single delay element, which is the luminance signal Ee subject to a time delay equal to two horizontal line intervals.

The luminance signal Eg delayed by 2H becomes the undelayed one Luminance signal Ea is added in adder 14, so that the added signal Eh of FIG. 6B results. That delayed signal Eg is attenuated by a factor of 1/2, and the instantaneous luminance signal Ea becomes the same Way dampened by a factor of 1/2. The summed signal Eh of Fig. 6D can therefore be represented as Eh = 1/2 (Ea + Eg) will.

The summed signal Eh (Fig. 6D) is delayed by the 1H Luminance signal Eb is subtracted in the subtracter 15, so that the difference signal Ec in Fig. 6E results. The difference signal Ec can be represented as Ec = Eb - Eh. The brightness level changes are in the difference signal Ec in the luminance signal from one line interval to the next and especially periodically Raised fluctuating level, which is superimposed on the luminance signal Ea.

As before, the difference signal Ec is fed to the limiter 21, which lets through the part of the difference signal Ec, which lies between the threshold values + L and -L. The signal Ed passed by the limiter 21 is shown in FIG. 6F. That The signal Ed passed through is inverted by the inverter 21 and the amplitude is adjusted by the amplitude adjustment circuit 23 and then added to the delayed luminance signal in the mixer.

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The difference signal Ec is fed to the amplitude filter 24, which lets through the part of the difference signal which exceeds the threshold values + L and -L. The output signal Ef des Amplitude sieve 24 is shown in Fig. 6G. The passed signal Ef is adjusted by the amplitude adjusting circuit 25 and then added in mixer 3 to the delayed luminance signal Eb and to the set inverted signal Ed. The output signal of the mixer 3 appears as a vertically aperture-corrected luminance signal Ey, as shown in FIG. 6H. That corrected Luminance signal has increased brightness level changes, and the fluctuating level that corresponds to the original luminance signal Ea (Fig. 6A) is superimposed is eliminated. The vertical aperture correction is thus performed without a line crawl component achieved.

In Fig. 3, the delay element 11 and the subtracter 12 act as a combined circuit to the relatively delayed Luminance signal Eb and the instantaneous luminance signal Ea to combine. The delay elements 11 and 13 act in a similar way in FIG. 5 with the adder 14 and the subtracter 15 together as a combination circuit for combining the instantaneous luminance signal Ea with the delayed luminance signal Eg. These combined signals are combined with the delayed luminance signal Eb further combined 1 In both embodiments the combination circuits are used to increase the brightness of the To increase the luminance signal from one horizontal line interval to the next and also to increase the luminance signal to raise periodically fluctuating levels superimposed by the operation of the camera 1.

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Claims (16)

3046544 SONY CORPORATION TOKYO / JAPAN It 4887 Vertical aperture correction circle s Ans ρ r. Ü. .c h, e iy video signal vertical aperture correction circuit, characterized by a delay element for delay of the video signal, a combination circuit for combining the delayed video signal with the instantaneous video signal, an amplitude filter connected to the combination circuit and at least passes the part of the combined signal that exceeds a certain threshold, a limiter, which is connected to the combination circuit to pass at least the part of the combined signal, which is below the threshold, and a mixer to convert the video signal with those from the amplitude sifter and limiter to combine transmitted parts. 2. Correction circuit according to claim 1, characterized in that the delay element has a delay generated by at least one horizontal scanning interval. 130038/0885 3. Correction circuit according to claim 1, characterized in that the mixer has an adder, to add the supplied signals, and an Inver ^ ter to invert the part fed from the amplitude filter to the adder, so that the video signal, the part of the the signal passed by the amplitude filter and the inverted part of the signal passed by the limiter combined Signals can be added. 4. Correction circuit according to claim 1, characterized in that the mixer has a device in order to add the part passed by the amplitude filter to the video signal and that of the limiter subtract the transmitted part. 5. Correction circuit according to claim 1, characterized in that the combination circuit has a Has subtracters to get the combined signal as a function of the difference between the supplied and relative to generate delayed video signals. 6. Correction circuit according to claim 5, characterized in that g e k e η η that the delay element produces a delay of one horizontal scanning interval. 7. Correction circuit according to claim 1, characterized in that the combination circuit is a Delay element has in order to generate a further delayed video signal, an adder by which further add delayed and supplied video signals and generate a sum signal, as well as a subtracter, the combined signal as a function of the difference between the delayed video signal and the sum signal to create. 8. Correction circuit according to claim 7, characterized in that the further delay element to the delay element is connected in series and one 13QQ38 / Q885 Delay generated by one horizontal scanning interval. 9. Correction circuit according to claim 1, characterized by means for adjusting the amplitude of the part of the combined signal / the at least is let through by the amplitude sieve. 10. Correction circuit according to claim 1, characterized by a color image recording device as a video signal source, which comprises means for adding a periodically changing switching signal to the video signal overlay. 11. Vertical aperture correction circuit for a color image pickup device that generates a video signal which is periodically varied changing switching signal is superimposed, so that there are periodically fluctuating levels of the video signal and the video image reproduced from the video signal has a line crawl effect, characterized by a Delay element for the video signal, a device which responds to the delayed and the undelayed video signal is responsive to the changes in the brightness of the video signal from one horizontal scanning interval to the next and to raise the periodically fluctuating levels, an amplitude sifter to divide the parts of the output signal of the enhancement means pass that exceed certain thresholds, a limiter that removes the part of the Lets output signals of the boosting device, the between the threshold values, and a mixer to convert the video signal and those from the amplitude filter and from the limiter to mix the passed parts so that the parts passed by the limiter are from the sum of the video signal and the parts passed by the amplitude filter are subtracted. 12. Correction circuit according to claim 11, characterized in that the threshold values above and below the mean level of the raised periodically fluctuating levels. 130038/0885 " ⁴ " 30485U 13. Correction circuit according to claim 11, characterized in that the delay device is a Delay generated by one horizontal scanning interval / and that the enhancement device has a subtracter, which produces an output signal which is a puncture of the difference between that by one horizontal scanning period delayed video signal and the undelayed video signal. 14. Correction circuit according to claim 11, characterized in that the delay element has a delay generated by a horizontal scanning interval, and that the enhancement means an additional delay element to produce a total delay of the video signal equal to two horizontal scanning intervals that an adder is provided to the video signal delayed by two horizontal scanning intervals and the undelayed video signal add, as well as a subtracter, to produce an output signal that is a function of the difference between the video signal delayed by one horizontal scanning period and the output signal produced by the adder is. 15. Correction circuit according to claim 13, characterized in that the mixer has an inverter, which is connected to the limiter to invert the parts passed by the limiter and an adder, which is connected to the inverter and the amplitude filter and which receives the undelayed video signal to convert the inverted parts and parts passed by the limiter, the parts passed by the amplitude filter and the undelayed part Add video signal. 16. Correction circuit according to claim 14, characterized in that the mixer has one with the limiter connected inverter-has to invert the parts passed by the inverter, and one with the 130038/0885 Delay element, the inverter and the amplitude filter connected adder to the delayed by one horizontal scanning interval video signal passed by the limiter to add the inverted parts and the parts passed by the amplitude filter. 17, correction circuit according to claim 11, characterized by level adjustment means to adjust the ratio of the amplitudes of the signals fed to the mixer optionally to be set. 130038/0885