DE2219372B2 - DEVICE FOR GENERATING A COLOR TELEVISION SIGNAL BY USING A PICTURE RECORDING EAR - Google Patents

Description

2 (1 -r- k) '

where k is in the range of 0 to 1, by subtracter (93, 97, 98) for subtracting the attenuated second pulses from the first \ o pulses and for subtracting the attenuated first pulses of the second mpulsen, and amplified by amplifiers (1Oi, 102, 103) for amplifying the output signals of the subtractors by a factor

2 k

The invention relates to a device for generating a color television signal mitteis an image pickup tube, on whose Pholoschichi an image is mapped by a strip filter , the strip filter alternately containing color strips of a first color and color strips of a second color, which are separated by intermediate transparent strips «■ and , and wherein the signal supplied by the pickup tube in first, the transparent strip corresponding pulses for the generation of a luminance signal and in two. the color stripes corresponding pulses for the generation of the color signal is divided. s <

Such a device for generating a color television signal is known from I) T-AS 12 44 237. Apart from the fact that the color stripes of the known stripe filter are scattering with a speci-independent irraisparcnz smaller than 1 and spectra-dependent 1% transparency, this known device neglects distortions which are caused by the conversion of the image which is space-modulated by the stripe filter into e; i _; electrical signal arise, flour

Ls wind different π. ihiem eini.icliei: ui> d fkompakien structure urn hall l-arbbildaulnahmesy stones developed, the one in ;! camera olives combined with a color stripe filter! e vcw end. One of these; Color image recording systems uses a color stripe filter which is formed by red, blue and green color stripes which are arranged accordingly at predetermined intervals in spatial repetition (radio frequency). The color stripe filter is arranged in close proximity to the faceplate of a camera or image pickup tube so that it spatially modulates an optical image focused on it by an optical device into red, blue and green components. The spatially modulated image is converted by the camera tube into an electrical image signal that contains three components, each of which has different fundamental frequencies, which correspond to the three primary color components. The Farbsi signals are separated from one another by filters, each of which has center frequencies which are essentially equal to the three fundamental frequencies of the components contained in the image signal. The separated components are then converted by a known method into a composite color video signal comprising components, e.g. B. Y, Q and / components contains. Difficulties have been encountered in manufacturing such color stripe filters containing red, blue and green stripes. since the strips are to be arranged in different spatial frequencies (repetition frequency).

Another system uses a different style Color stripe filter that has index stripes in addition to the red, blue and green color stripes.

The color stripe filter is incorporated into a camera tube in the same manner as that in the previous one; The system described for obtaining an image signal · · is incorporated. This image signal includes an index signal caused by the index strip and three color signals. The index signal is used /.um 1 rennen de: color signals from each other. It should be emphasized that the width of each stripe of the stripe filter should be as small as possible - which makes the production of the stripe filter difficult - since four diffusers correspond to a single picture element. It is emphasize zn cbenlali- that only one third or a quarter which is emitted from the optical image and used to the stripe filter focus light amount to form the luminance signal in the previously described systems, which mainly regulates the resolution of a video image of a ¹ Image reproduction device, for example a television receiver, is reproduced.

It is therefore the task of the subject of the application des, a facility of the type specified at the beginning to design that distortions are based on the V, speech-susceptibility of the image pickup tube. \ ermicUcn will be.

According to the invention, the task is performed by a Correction process solved, the characteristics of which are in cm / oak part ties claim 1 are included.

The device according to the invention has the following properties

i. A generated image signal ei. '. Ha!' a Leuchuiichi «. component one with a sufficiently large intensity ^and; n relatively tight :; l -! - i.ijuen / .spektnim i Es kanu ei !. Luminance designa! generate, ii: ^ ^:. ^ intensity as a function of oeii lntens: taie :: ■ - w larticomponents in the image signal hai 5. Es Kan ;: generate an image signal. da- 1 arbt.ompo neniei, m: i contains a sufficiently large range of efficiency, although the luminance component> ies Bil.i .-. ign.i, s is sufficient: high intensity hai

4. It can produce an image signal containing color components with uniform intensity.

5. The need for registration and the two-tone mirrors required in a multi-tube system are avoided, so that the image pickup tube has a simple structure.

The invention is explained in more detail in the following, in the form of schematic drawings using exemplary embodiments:

F i g. 1A shows a sectional view of a conventional color image pickup system;

F i g. 1B shows a view of a color stripe filer, that in the system of FIG. 1 is used-,

F i g. Fig. 2 is a diagram showing a waveform of an output signal from the system of Fig. 1;

Fig. 3 shows a view of an inventive Color stripe filter;

F i g. 4A, 4B, 4C and 4D show sectional views of FIG various types of screen arrangements available for the device according to the invention;

Fig. 5 shows a sectional view of an image signal generator of the device according to the invention;

Fig. Fig. 6 is a diagram showing a waveform of an output image signal of the image signal generator according to Fig. 5;

Fig. 7 shows a block diagram. a signal processor built into the image signal generator;

Figs. 8A to 8F show various waveforms, in the signal processing according to FIG. 7 occur:

F i g. Fig. 9 is an explanatory diagram. ' the Operation of the facilities according to FIG. 5 and 7:

Fig. 10 shows in a graphical representation Sensitivity of an ordinary vidicon:

Fig. 11 illustrates in a graphic presen- tation the distortion of an output signal of the vidicon with the sensitivity of Fig. 10-

Fig. 12 shows an illustration for explaining the Correction operation of the signal processing device according to the invention;

Figure 13 is a block diagram of a correction circuit in the signal processor of Figure 13. 7th

Corresponding parts are numbered in the same way in the illustrations.

Brief description: A device according to the invention for generating a color television signal has a Bildsignaigenerator with a single image pickup or camera tube in which a color stripe filter is built, and a signal processor for Umwan deln an image signal generated by the signal generator in a composite video signal! of a known type. This colored strip filter consists of a number of white or transparent strips alternating with two types of colored tires. for example red and blue stripes. The image signal therefore contains a luminance component. caused by the transparent stripes, and two color signals caused by the color stripes. In the signal processor, first the luminance and the two color signals and then the two color signals are separated from one another by phase detection or frequency detection.

In Fig. 1A shows a typical conventional color image pickup system having a color stripe filter! 0 and an objective lens 51 for focusing an object 12 on the surface of the color stripe filter 10 so that an optical image of the object 12 is formed on the surface of the stripe filter 10. The strip filter 10 includes index strips and red, green, and blue strips arranged in order so that the optical image is spatially modulated as it passes through the strip filter 10. The Indexsireifen example, consist of a fluorescently> centers material and are excited by light from a light source 13 which is arranged in the sewing of the strip filter 10th The spatially modulated optical image is radiated onto the face plate 14 of a vidicon 15, which has a screen arrangement

ίο has a transparent, electrically conductive layer 16, which is arranged on the back of the face plate 14, and a photoconductive layer 17 contains. the photoconductive layer 17 is scanned by an electron beam 18 emitted by an electron gun 19

is sent out inside a piston 20 of the Vidikons 15 is arranged. Since the spatially modulated optical image is radiated onto the photoconductive layer 17 electrical charges are generated depending on the conductivity of a point, which is the electron

: o sfrah! 18 hits, saved. The electrical charges flow to ground via a resistor 21 and thereby generate a voltage signal at a sounding point 22. The voltage signal is via a coupling capacitor 23 by a suitable Signalver

The work facility was added.

In Fig. 1B is that in the system of FIG. ! - \ used color stripe filter 10 in a coarsened Scale illustrated; the Red. green uiu: blue colored stripes and the index stripes are mn. the

ι; Reference numerals 24, 25, 26 and 27 denote !.

In FIG. 2 is a wave ft -m of the voltage signal ge / eigi generated by the vidicon according to FIG. 1A. that an index signa! I ·. t arbsignale R \ C /. and />'door red. contains green and blue.

is in Fig. 3 a kind of color stitchery 30 is illustrated, that is used in the execution according to the invention; becomes and transparent or white quarrels 51 and includes red and blue stripes 32 and 33. The white stripes 31 and the color stripes 32 and S3 miicI arranged alternately with each other in a direction perpendicular to the longitudinal direction of each contest. the Strips 31, 32 and 33 can each have different widths; however, the strips preferably have a common width from the Hallte to twice the diameter of the first luminous spot to the Sampling of an optical image passed through the strip filter. For example, if the effective tank horizontal scanning wave and the spot diameter of 12.7 mm and 20 microns, respectively, it is desirable.

so that the width of this strip is 20 microns. The strips 31, 32 and 33. those mentioned in the above ;. Order are arranged, are preferably surrounded by a black frame 34. Is · to notice that the repetition frequencies / the i-work-

ss stripes 32 or 33, for example '■'-; - to ' Vrnal st) t. just like the repetition frequency of the Iran-specific stripes 31. so that the image signal spatially modulated by the color stripe filter 30 has a light density component with a high intensity and frequency uric:

ΐΊ> color components; . \>'. nicelrigcr intensity around: contains frequencies. It is a physiological fact that human eyes are more sensitive to the 1st finite Inc component than to the 1 color components. DaheT Can an image signal that r-ite:

(> - ■ Use of the inventive method !; te: ■ is generated by converting a suitable signal processing 111 into a cheap video signal.
The strip filter 3 mentioned in the previous !: (

can be built in various types of screen arrangements, some of which are shown in FIGS. 4A to 4D as Example are given.

In the embodiment according to FIG. 4A, the color stripe filter 30 is arranged on a transparent substrate 40, which consists for example of glass and has a thickness of about 2 to 3 mm when it forms a face plate of a camera tube. A transparent electrically conductive layer 42 made of a metal oxide such as SnO2 and InCh is arranged on the color stripe filter 30. A photoconductive layer 43 is formed on the electrically conductive layer 42.

Another type of screen arrangement is shown in FIG. 4B , which has the strip filter 30 arranged on a surface of a fiber optic plate 44 . A transparent electrically conductive layer 42 is arranged on the other surface of the fiber optic plate 44. A photoconductive layer 43 is also arranged on the electrically conductive layer 42.

In Fig. 4C, another kind of screen arrangement is shown, which has the disposed on a surface of a glass plate color stripe filter 30. A transparent, electrically conductive layer 42 is arranged on the other surface of the glass plate 40. A photoconductive layer 43 is also arranged on the layer 42.

In Fig. 4D another screen arrangement is shown, which has the color stripe filter 30, which in this case consists of an electrically conductive material. on A photoconductive layer 43 is arranged on one surface of the filter 30. On the other face of the filter 30 is a transparent electrically conductive layer 42 is arranged. The conductive layer 42 is on a Glass plate 40 arranged.

5 illustrates a device for generating a color television signal according to the invention. Jie a screen arrangement 50 with the strip filter according to FIG. 3 and with a structure according to FIG. 4A through AD contains. The screen arrangement 50 sits on a face plate of a camera tube 51, for example a vidicon with a piston 52 which is surrounded by vertical and horizontal deflection coils 53 and 54 and a compensating coil 55 . In the piston 52, an electron gun arrangement 56a is provided which emits an electron beam in the direction of the screen arrangement 50. The electron beam emitted in this way is deflected vertically and horizontally so that it scans the rear of the screen arrangement 50. The Schinn arrangement has an electrically conductive layer which is connected to a positive terminal of a DC voltage source E via a resistor Ran. whereby the electron beam is accelerated in the direction of the screen 50. A negative connection of the voltage source E is connected to ground. In front of the front plate of the vidicon 51, an optical device 56 for focusing an object or image 57 to be recorded is arranged on the front plate of the vidicon 51. The optical device 56 has an objective lens 58 with a diaphragm 59 and a semicircular cylindrical lens 60 which sits between the lens 58 and the face plate of the vidicon 51. The optical device 56 can further include an annular or otherwise shaped reflector 61, which sits between the lens 60 and the faceplate, a tubular shielding element 62, which sits between the reflector 61 and the faceplate, and one or more Vorerleuc'ntungsliehtquellen 64. die are arranged on the peripheral wall of the shielding member 62.

contain. If necessary, the reflector 61, the shielding element 62 and the light source 63 can be omitted. With this arrangement, light rays emitted by the pre-illumination light sources 63 are reflected on the reflector 61 and radiated onto the faceplate of the vidicon 51, so that an optical image focused through the lenses 59 and 60 onto the faceplate is present with a certain brightness. By scanning the electron beam emitted by the electron gun 56a, the optical image is converted into an electrical image signal which appears at a circuit node 64 and is picked up by a suitable signal processor via a coupling capacitor C and an output connection 65, s F i g. 6 is a graph showing a waveform of the output from the device, ie, the image signal generator of FIG. 5 generated image signal, wherein the abscissa and ordinate axis represent the time and the amplitude. It can be seen that the: o waveform has maximum values Mu which occur periodically and minimum values / V / and Mn . which sit between the maximum values Λ / η. The maximum values Λ7 »and the minimum values A / wound Mn correspond to the white, red and blue stripes of the strip filter, respectively. : s In Fig. 7 is a signal processor / to convert the data from the image signal generator of FIG. 5 produced image signal into a composite video signal illustrated, which has a preamplifier 70 having an input connected to an input terminal 71 Eingangsan- \ o-circuit. The input terminal 71 is connected to the output terminal 65 of the generator according to FIG. ", So that the image signal is applied to the preamplifier 70 as shown in FIG. B. An output terminal of the preamplifier 70 is connected to the input terminals of a delay circuit 72 and a differentiating element 73. An output connection of the differentiating element 73 is connected to an input connection of a Schmidt trigger circuit 74, which has an output connection connected to the input connections of a limiter 75. The limiter 75 forms pulses from the output signal from the Schmidt trigger circuit 74 If necessary, the limiter 75 can be omitted. An output terminal of the limiter 75 is connected to input terminals of first, second and third sampling pulse trains 76, 77 and 78, the respective sampling pulse trains depending on generate the impulses applied to them Connection of the sampling simulators 76, 77 and 78 are connected to input terminals of a first, second and third sampling gate 79, 80 and 81, respectively. An output terminal of the delay circuit 72 is connected to an input of a hold circuit 8? which has an output terminal connected to the other input terminals of the first, / wide and third scanning gates 79, 80 and 81. The hold circuit holds an input signal applied to it at a DC voltage level. Output connections of the scanning gates 79, 80 and 81 are connected to input connections of a correction circuit 83. which has output terminals connected to input terminals of a wave shaper 84. Output terminals of the waveform shaper 84 are connected to a matrix circuit 85 comprising 6 <; Has output terminals which are connected to input terminals of a modulator 86. An output terminal of the modulator 86 is connected to an output terminal 87.

A. ana 'stiii

dri je w with

de ι SF

on Sig dei 73rd at

wii Gl <de Ra Da liej at three (Pr wc door un 'K; fei lic; come to us the urr wed un mi de

Bi eil St Fe St to de be

Using the 1 i g. 8A to 81 'is now the Operation of the signal processor according to FIG. 7 explained.

^{When the image signal shown in FIG. 1 is applied} to the input terminal 71, a signal analogous to the image signal appears at the output terminal of the preamplifier 70 and is applied to the delay circuit 72 and the differentiator 73. FIG. 8B is a waveform of the signal differentiated by the differentiator 73 is shown which changes its polarity from positive to negative when the image signal assumes a maximum Mh, and on the contrary from negative to positive when the image signal assumes a minimum Mr or Mb 8C is applied to the limiter 75, which then generates a pulse signal shown in FIG Pulse appears on the falling edges of the pulse signal from the limiter 75. The output of the limiter 75 is also applied to the second and third en sampling pulse generators 77 and 78 which then respectively generate second and third sampling pulses c which alternate with one another and appear on the rising edges of alternate pulses of the pulse signal from the limiter 75, as shown in FIG. 8E and 8F.

The output signal of the preamplifier 70 is on the other hand at the 1 delay circuit 72, which delays the ya signal by a delay time which is equal to the total delay time of the differentiator 73, the Schmidt trigger circuit 74, the limiter 75 and the sampling pulse generators 76, 77 and 78. The delayed signal from the delay circuit 72 is supplied to the hold circuit 82 which holds it at a DC voltage level which is determined on the basis of the size of the image signal which corresponds to the black frame of the color stripe filter according to FIG. 3 corresponds. The delayed and held (biased) signal is applied to the first, second and third sample gates 79, 80 and 81 which sample the signal with the first, second and third sample signals, respectively. The sampled signals (sample signals) from the sampling gates 79, 80 and 81 are corrected by the correction circuit 83 to remove the distortion in the image signal caused by the responsiveness of the camera tube in the system of FIG. 5 is caused. The sampled and corrected signals are applied to wave shaper 84, which shapes the signals into analog signals that envelop the corresponding sampled signals, respectively. The shaped signals are provided to the matrix circuit 85 which then converts them to the known luminance (Y) and color ((?, / -) signals. The Y, Q and / signals are then applied to the modulator 86 , then the Q and / signals modulated and mixes the modulated Q and / signals with the signal V '. the mixed signal or a composite color video signal appears at the output terminal 87.

F i g. 9 illustrates another example of the image signal generated in the generator of FIG. 5 was generated by a horizontal scan of the electron beam on the face plate of the vidicon 51. In this case, since a dark scene has been focused on a portion of the faceplate corresponding to a time interval up to a time t , this portion is irradiated only with the light beams from the pre-illumination light source 63, so that the image signal has small amplitudes up to the time f. The small amplitude of the image signal is used by the sampling signal generators in the signal processor for the correct generation of the sampling pulse signals. It should be noted that the Abtas'.impulsgeneralor cannot be operated without the image signal. The luminous intensity of the pre-illumination light source 63 is selected in such a way that the front plate is supplied with a pre-brightness of 5 to 10% of the greatest brightness in the focused scene. The pre-brightness is favorable for avoiding undesired fluorescence which occurs in the phosphor layer used in the vidicon.

Since a light scene is focused on a different section of the front face, the image signal has greater amplitudes after time t , as shown in FIG. 9 is shown. If this image signal with the maximum values Mw and the minimum values Mh and Mean is available to the Sigr.alververarbeitung according to FIG. 7, the wave shaper 84 generates envelopes shown by a chain line A, a broken line B, and a broken line C. The envelopes, 4. B and C are the luminance signal, the red color signal and the blue color signal, respectively.

A typical characteristic of an ordinary vidicon is shown in Fig. 10, in which the axes of abscissa and ordinate represent spatial frequency and responsiveness, respectively. If a light input signal with a spatial frequency / '·. irradiated onto the face plate of the vidicon as shown by a broken curve D , therefore, an output signal as shown by a continuous curve E is generated from the vidicon. The correction circuit 83 corrects the distortion in the output signal from the generator vidicon.

In Fig. 12, there is shown a waveform of the output signal from the image signal generator which has maxima shown by Vi, Y: ...) "·. · ;. Y _n and Υ ,, - ι , and minima shown by Ci. O ... O- ;, Cn and Cr ■; are shown. The maximum and minimum values c Vn and O> are corrected to values Yr and C \ < by the following equation:

1 ifc I / 1 k ^ _fC:

Ik '"V I + A

2k

where k represents the responsiveness of the vidicon at the spatial frequency Λ.

Fig. 13 shows a circuit arrangement of the correction circuit 83 of the signal processor according to FIG. 7 showing the sample image signal based on the above Corrected equations. The circuit arrangement has a first, a second and a third holding circuit 90, 91 and 92 with input terminals connected to the first, second and third scanning gates 79, 80 and 81, respectively are connected. An output terminal of the holding circuit 90 is connected to an input terminal of a first Subtracter 93, having an input terminal of a fourth holding circuit 94 and having an input terminal a second adder 95 connected. An output terminal of the second holding circuit 9t is with one input terminal of a first adder 96 and one input terminal of a second subtracter 97 connected. One output terminal of the fourth holding circuit 94 is connected to the other input terminal

609 523 226

Circuit of the second adder 95 connected. One output terminal of the third holding circuit 92 is connected to the other input terminal of the first adder 96 and to one input terminal of a third subtracter 98. An output terminal of the first adder 96 is connected to an input terminal of a first attenuator 99, one output terminal of which is connected to the other input terminal of the first subtracter 93. An output terminal of the second adder 95 is connected to an input terminal of a second attenuator 100 , one output terminal of which is connected to the other input terminal of the third subtracter 98.

Output terminals of the first, second and third subtractors are connected to input terminals of a first, second and third amplifier 101, 102 and 103 , respectively. Output terminals of the amplifiers 101, 102 and 103 are connected to the wave shaper 84.

If, during operation, the scanned luminance and color components Yn, Cn-1 and Cn are applied to the first, second and third holding circuits 90, 91 and 92, which respectively cool the scanned components applied to them until the following scanned components are applied to them, the latched sampled signals Cn-1 and Cn are applied to the input terminals of the first adder 96, which then generates a signal with an amplitude (Cn-; + Cn). The (Cn-i + C / signal becomes a signal with the amplitude

1- * C ₁₁ .., + C ₁₁ I + £ ■ 2

attenuated, which is applied to the first subtracter 93 together with the signal Yn. An output from the first subtracter 93 becomes from the amplifier 101 to

1 + k 2 k

-k

10

If the signals Yn, i. Cn and Cn -1 applied to the holding circuits 90, 91 and 92, the fourth holding circuit 94 holds the signal Yn. The signals Yn- · ι and Yn from the holding circuits 90 and 94 are applied to the second adder 95, which then generates _{a signal (V n} + Yn ·!). The signal ( Yn + Yn. Ϊ) becomes a signal by the / wide attenuator 100

(Y ₁₁ ■ Y _n , \ 2

I + A-

muffled. The signal

'S \ -k

I + k

and the signal Cn are present at the second subtracter 97, which then generates a signal

r -

+ k

which is then generated by the amplifier 102 too

/ I + k V 2k

\ ^C "\ + k

is reinforced. In the following moment the amplifier generates a signal

reinforced.

The strip filters given above, for example, have strips of the same width. It is however, it should be noted that the strips can be of various widths if desired.

Here / u ^l >Hl; in / -cichrsunsiiMi

Claims (1)

Claim: Device for generating a color television signal by means of an image pick-up tube, on the photo layer of which an image is imaged by a strip filter, the strip filter alternately containing color strips of a first color and color strips of a second color, which are separated by intermediate transparent strips, and which is supplied by the pick-up tube Signal ir. First pulses corresponding to the transparent strip for generating a luminance signal and into second pulses corresponding to the colored strips for generating the color signal, characterized by adders (95, 96) for adding two successive pulses (Yn. Ynt) of the first pulses or two consecutive pulses (Cn, Cni) of the second pulses, by the adders respectively downstream attenuators (99, 100) for attenuating the addition signals (Yn- Ym or Cn + C? /) by a factor