DE2261077C3 - Device for generating color television signals - Google Patents

Description

The invention relates to devices for generating color television signals.

It is known that such small-sized and inexpensive color television cameras can be constructed can that the television camera contains two image pickup tubes that operate with a luminance separation, wherein an image pickup tube is used to generate a luminance component luminance signal while the other image pickup tube generates the color separation signals or color value signals. Many of the familiar simplified Color television cameras are therefore based on this principle and use two image pickup tubes.

Typically, a television camera of this type is provided with a color stripe filter located in the optical system of the image pickup tube for generating the color signals is located, and the color signals are derived by phase separation or frequency separation. Has the well-known color television camera However, the color stripe filter has a very complicated structure, and this applies to both arrangements of the Derivation of the color signals too.

If the color signals are derived with the aid of a phase separation, it is necessary to use sampling pulses based on information derived from index strips of the color stripe filter. As a result, it is necessary to provide a special interrogation pulse generator of complicated circuit.

In the color telephoto cameras mentioned above furthermore, point-sequential color information signals by a storage and interrogation circuit in sumultaneous Converted color information signals. This creates high-frequency noise, which is reflected in the point-sequential color information signals are transferred to the Zett axis through this circuit. The

This turns high-frequency noise into an annoying one Low frequency noise converted and the signal-to-noise ratio generated by the camera This degrades signals.

Another difficulty is that when the color signals are derived with the aid of a frequency separation circuit and if a color stripe filter is omitted from the optical system, expensive relay lenses and the like are used, so that it is difficult to obtain good optical images on the color stripe filter of the photoconductive Generate layer of the image pickup tube. The color image pick-up tubes are therefore required to be large in size have and are very expensive.

Another difficulty is that when there are two or more image pickup tubes in the camera are used to generate color signals, there are color errors caused by non-uniformities in the color tone between the image pick-up tubes of the camera, so that images with good properties because of the Non-uniformities and deviations in the properties of the image pickup tubes are not achieved can that z. B. due to temperature dependencies and changes over long periods of time are.

DT-AS 14 62 842 discloses a device for generating color television signals with an image pickup tube known, which is provided on its front with a color stripe filter that has a number of Having groups of filter strips which are sequentially repeated in succession, each group having one contains the first filter strip, which is designed in terms of light transmission so that it the light lets through one of the three color values of an additive color mixture, contains a second filter strip of which at least a part has such a light transmission that it the light of a mixed color from the Color value that passes through the first filter strip and one of the other two color values, and a clear third filter strip which transmits white light, the first, second and third filter strips parallel to each other and are arranged adjacent to one another, wherein the image pick-up tube generates an output signal which in Superposition of a direct signal, a first amplitude-modulated color signal with a first carrier frequency and a second amplitude-modulated color signal having a second carrier frequency, at which further a first separation circuit separates the direct signal from the output signal of the image pickup tube, a second separating circuit the first amplitude-modulated color signal from the output signal of the image pickup tube separates, and a third separation circuit, the second amplitude-modulated color signal from the Separates output signal of the image pick-up tube, in which further a first demodulator circuit the first amplitude-modulated color signal demodulated after separation, and a second demodulator circuit demodulate the second amplitude-modulated color signal after separation, and in the case of a matrix circuit connected to the outputs of the first isolating circuit and the first and second demudulation circuit and the desired output signals of the three primary colors or the three difference colors generated

If one takes a closer look at the device described in DT-AS 14 62 842, it emerges that the carrier frequencies of the modulated oscillation KRE cos Ri and the modulated oscillation KbEs cos et are set to 4 MHz and 5.5 MHz . The frequency of the error signal, which arises from the cross-modulation of the two aforementioned modulated oscillations, is 1.5 MHz. This error signal passes through the low-pass filter provided in the circuit, so that the error signal is added to the non-modulated signal at a frequency of 1.5 MHz. The resulting signal is fed to a matrix circuit without being demodulated so that the sinusoidal

ίο The error signal is also reflected in the output size of the Matrix circuit found again The resulting signal therefore causes banding that is annoying to the eye the picture tube. To overcome these difficulties, a beat frequency generator is provided.

The elimination of the error signal by the output signal of this beat frequency generator requires However, a difficult adjustment, since the non-linearities of the image pick-up tube and the The transistors used each turn out different, the difficulty arises that a readjustment must be done every time the image pickup tube is replaced or when Amplifier tubes or transistors need to be replaced.

Furthermore, from DT-OS 15 37 501 an image recording system known for color television cameras that works with two image pickup tubes and in which the image pickup tube to generate the color signal with a color strip filter from two types of filter strips, the are arranged alternately next to one another, is provided. This also results in this known system Disadvantage that the output chrominance signal of the matrix is distorted. It also requires here to Adjustment of the device special exercise.

The invention is based on the object of making the operation of the camera much easier by that no additional correction circuits are required and that the three color value signals from a single image pickup tube can be derived in such a way that a special re-adjustment or Adjustment is also unnecessary when changing the tube.

According to the invention, this object is achieved in that two of the three filter strips have the same width and the third filter strip has a width twice that of the other two strips, so that the second carrier frequency is twice the first carrier frequency that the third isolation circuit is one Contains a delay circuit that reduces the output signal of the camera tube by half the period of the first carrier frequency delayed that an adding circuit the output signal of the image pickup tube and the delayed output of the delay circuit is added, and that a bandpass filter on the Output signal of the adding circuit responds and the second amplitude-modulated color signal from the Output signal of the adding circuit passes.

If one forms the strip width of the three filter strips in this way, then one obtains advantageously as the carrier frequency of the second amplitude-modulated oscillation, a frequency that is exactly the same as the Double the carrier frequency of the first amplitude-modulated oscillation. In this case a Beat frequencies occur that are amplitude-modulated by cross-modulation between the first and second Oscillation arises and is caused by a non-linearity of the tube and the amplifier

is. However, the low-pass filter cannot do this sinusoidally running error signal of the beat frequency push through. There is therefore no sinusoidal error signal at the output of the low-pass filter, which could degrade the image quality.

If one forms the width of the three filter strips in the specified way, then one can also use the train third isolating circuit in the manner characterized in claim 1. This results in a Improvement of the signal-to-noise ratio of the second amplitude-modulated oscillation.

It is recommended that the second filter strip and the third filter strip have the same width and that the first filter strip is twice as wide as the second and third filter strips.

The arrangement can also be made so that the first filter strip and the second filter strip the have the same width and that the third filter strip is twice as wide as the first and second strips.

Finally, the arrangement can also be made so that the first filter strip and the third Filter strips the same width and the second filter strip twice the width as the first and Third filter strip has that the second filter strip has a first part with such a light transmission chain icteristics has that it light one of the transmitted by the first filter strip color value and one of the two other color values mixed color lets through, and a second part, the one has such light transmission that it can light one of the color value of the first filter strip and that of the other of the two color values lets through mixed color, whereby the first and second part are left out parallel strips of the same width as the first and third filter strips.

The device described combines the advantages of the usual phase separation and frequency separation. It is designed so that circuits for generating query pulses and memory and Inquiry circuits or the arrangement of a beat frequency generator are not required. Through this it is possible to get color television signals with a very good signal-to-noise ratio.

Further features and additional properties of the invention will become apparent from the following description of FIG Embodiments, which are explained in more detail in connection with the drawings. In the Drawings is

1 shows a circuit of a color television camera with two image pickup tubes and a luminance separation system,

Fig. 2 is an enlarged partial view of a color stripe filter for use in a device according to the invention,

Fig.3 is a diagram showing the energy distribution of the transmitted light shows when white light hits the color stripe filter according to FIG. 2 is projected,

F i g. 4 shows a graph of the frequency dependency the output signal of the image pick-up tube for generating color signals in a device according to the invention,

F i g. 5 is a block diagram of a color signal demodulation circuit according to the invention,

F i g. 6A and 6B show the sequential relationship of the adder of FIG. 5 input signals supplied,

F i g. 7 is a diagram showing the course of the output signals of the adding circuit according to FIG. 5 indicates

F i g. 8 is an enlarged partial view of a second embodiment of a color stripe filter according to FIG Invention,

F i g. FIG. 9 is a diagram showing the distribution of the energy generated by S of the color stripe filter according to FIG. 8 let through Light indicates

Fig. 10 is a frequency diagram of the output signal the image pickup tube,

F i g. 11 is a block diagram of a second embodiment a color signal demodulation circuit,

Fig. 12 is a block diagram of a third embodiment a color signal demodulation circuit,

F i g. 13A and 13B are diagrams showing the sequential Relationship of the input signals of the adding circuit according to FIG. 12 shows as a function of time,

FIG. 14 is a diagram showing the profile of the output signal of the adding circuit from FIG indicates

F i g. 15 is a block diagram of a matrix circuit according to the invention,

16 is an enlarged partial view of a third Embodiment of a color stripe filter and

Fig. 17 is a diagram showing the transmitted light distribution of the color stripe filter according to Fig. 16 indicates.

In Fig. 1 the structure of a color television camera with two image pickup tubes is shown schematically, which has a separate image pick-up tube for obtaining the luminance signal. The one of one Object 10 outgoing light rays pass through a camera lens 11, and a part of the light rays is reflected by a semi-reflective mirror 12 and forms an optical image of the object 10 on the photoconductive surface of the image pickup tube 15 for generating the luminance signal. At the same time penetrates the other part of the light rays that pass through the lens 11, the mirror 12 and forms an image of the object 10 on the color strip filter 13.

The color strip filter 13 creates an optical image of the object 10 on the photosensitive Surface of the image pickup tube 14, which is divided according to the filter strips of the filter 13, for Generation of the color signals, with the help of a lenticular lens (not shown), the z. B. between derr Filter 13 and the front glass screen of the tube 14 is arranged. The luminance signal of the Bildauf Acquisition tube 15 and the color signals of the image pickup tube 14 are processed in a circuit 16 and < transmitted as color television signals.

The construction of a color stripe filter 13 which can be used in connection with the device for generating the television signals according to the invention is shown in FIG. 2 shown. The color stripe filter 13 consists of successive and closely spaced identi groups of stripes, of which each group i parallel and continuous arrangement a first filter strip Cl with a width of a / 2, a second filter strip C2 with a width of a / 4 and a third Contains filter strip C3 with a width of a / 4 in d <specified order. These strips C CI and C3 run in the longitudinal direction Y, as ai F i g. 2 results, this direction being perpendicular to d <horizontal scanning direction X , and are geni regularly arranged in the order described. The spatial frequencies of the filters Ci, Cl and C3 all have the same frequency value. The filter strips Ci, C2 and C3 have ύ

the following transmission properties for the incident light. The first filter strip CX lets light of a color value of the three basic colors red, green and blue through. The second filter strip C 2 transmits light of a mixed color consisting of the first basic color which passes through the first filter strip and one of the two other color values, ie a color which differs from that which passes through the first filter strip. The third filter strip C3 lets light of all colors through.

The second filter strip C2 preferably has a light transmission characteristic so that it is able to transmit light with a color having the following relationship with respect to the primary color, depending on whether the light transmitted by the first filter strip Ci is red, green or blue is.

Light of the color value that
passed by the first filter strip Cl
will

Color of the light that is transmitted through the second filter strip CI

Red light
Green light
Blue light

Magenta (red-blue) or yellow (red-green)

Yellow (red green) or cyan blue (teal)

Magenta (red-blue) or cyan (blue-green)

In an exemplary embodiment of the color stripe filter of the specified type, let the first filter strip C 1 pass through blue light (B). The second filter strip Cl is then able to transmit the light of a mixed color (ie magenta [M]) of blue light (B) and red light (R) . The third filter strip C3 is able to transmit light of all colors, ie white light (W), which is a mixed color of red light (R), green light (G) and blue light (B).

If white light (W) is projected onto this color strip filter 13, which has the filter strips Cl, Cl and C3 with the specified light transmission properties, a light transmission diagram as shown in FIG. 3. In this graphic representation, the intensity distribution is plotted on the X-axis in the horizontal direction. The blue light (B) is applied continuously in the horizontal direction, which passes through all the filter strips C1, C1 and C3. The red light (R) is only allowed through with a width of all , while the distances are a / 2, since it is only allowed through by the filter strips C1 and C3. The green light (G) is only allowed to pass with a strip width of a / 4, the distances being 3a / 4, since it is only allowed through by the filter strips C3.

If a color stripe filter with the stripes Ci, Cl and C3 of the type described as a filter 13 in a color television camera according to FIG. 1 is used and white light (W) is imaged from an object 10 via the lens 11, output signals corresponding to the frequency bands 1 and II in FIG. 1 are obtained. 4 from the image pickup tube 14 for generating the color signals. ·

Since the blue light (B) passes through all of the filter strips Cl, Cl and C3, these signals appear only in the frequency band indicated by curve 1 in FIG. 4 is indicated. The color resolution of the strip filter 13 is designed in such a way that the spatial frequency of all filter strips Cl, Cl and C3 has the same value, which is designated here by / "1. For this reason, the red light (R) and the green light (G ) in a frequency band II according to FIG. 4 as a signal that is obtained by amplitude modulation of a carrier wave with the value f \ as spatial frequency / 1, as can be seen from the arrangement of the filter strips.

In the following, a signal which is within the frequency band of curve I in FIG. 4 lies as a direct one Signal denotes, while a signal which is in the area of curve II of the frequency of the frequency diagram is referred to as the "first modulated color signal". The one at the exit of the image pickup tube 14 generated color signals can also be represented in such a way that they appear as a superposition of a first modulated color signal and a direct signal.

This superimposed output signal from the image pickup tube 14 is fed to a low-pass filter 20 or a band-pass filter 21 of a color signal demodulation circuit 22, which in an example in the block diagram of FIG. 5 is shown. Here becomes the above mentioned direct signal in area I tapped at the low-pass filter 20, while the first modulated color signal of the area II at the bandpass filter 21 is tapped.

The modulated color signal of the band-pass filter 21 becomes a demodulation circuit 22 is supplied.

As described above, the blue light (B) is transmitted from the entire surface of the color stripe filter 13, while the red light (R) is transmitted with a stripe width of a / 2 and a pitch a of the filter stripes, while the green light (G) with a strip width of a / 4 and with a strip spacing of 2a the filter strip is allowed through. The distance a and the distance frequency / 1 have a relationship expressed by the equation / "I = IZa.

The direct output signal of the low-pass filter 20 is the sum of a signal (SB) which comes from the blue light (B) , a signal (SR / 2) which corresponds to the mean value of the red light (R) and a signal (SGIA) which corresponds to the average value of the green light (G). As a result of the rectification taking place in the demodulation circuit 22 of the first modulated color signal which is taken from the bandpass filter 21, the signal obtained in this way corresponds to the sum of a signal (SR / 2) of the mean value of the red signal (R) and a signal (SGIA ) the mean value of the green light (G). It should be noted that the coefficients 1/2 and 1/4 in the signals described above represent numerical values which relate to the case in which the light transmission factors are all the same filter strips. If these <transmission factors are different from one another, then who the coefficients are also different. By appropriately selecting the matrix mixing ratios of the signals in a matrix circuit 23, which will be described below, it is possible to compensate for the mutual differences in the coefficients in order to obtain the desired signals in this way.

The output signals of the low-pass filter and the demodulating circuit 22 become a matrix shell device 23 supplied.

The output of the image pickup tube 14 we

an adder circuit 25, either directly or through a delay circuit (delay line) 24. The delay line 24 has such a characteristic that it delays a signal by a time value equal to half the period (a / 2) of the spatial frequency Π of the filter strips corresponds to, ie a time corresponding to a period (a / 2) of an oscillation whose frequency is twice the value of the carrier frequency f \ .

When a signal shown in FIG. 6A is fed directly from the image pickup tube 14 to an input terminal of the adding circuit 25, a signal according to FIG. 6B, which is delayed by a period (a / 2) which is half the period (a) of the signal of FIG. 6A corresponds to delay line 24, fed to the other terminal of the adder circuit. The two F i g. 6A and 6B show specific examples of combinations of signals (SB) for blue light, signals (SM) for magenta and signals (SW) for white light, which are arranged along the time axis.

The input signals fed to the adder 25 according to FIG. 6A and 6B are added, and at the output of the adder circuit 25, that shown in FIG. 7, for example, the signal shown and fed to a subsequent bandpass filter 26. As shown in FIG. 7, the output signal of the adder circuit 25 is a signal which results from the superposition of a green signal (SG) with a period of a / 2 and a signal which is the sum {2SB + SR) of a signal 2SB, which is double Value corresponds to the blue signal (SB) and forms from a signal (SR) for red light.

If the frequency of a carrier wave during a time period a is denoted by f2 , where f2 is equal to 2 / Ί, the signal SG for green light according to FIG. 7 can be represented as a signal which occupies the frequency range of curve III which is shown in FIG. 4 is shown in phantom. In other words, the signal of the frequency band III, which is taken from the output side of the adding circuit 25, is a second modulated color signal, which results from the amplitude modulation of a carrier oscillation of frequency (1 by the green signal SG .

The output signal of the adder circuit 25 is fed to the band-pass filter 26, as mentioned above, where the second modulated color signal of the band IH is derived and demodulated by a demodulation circuit 27, so that the green color value signal SG results. The green color value signal SG is fed to a matrix circuit 23 together with the output signal of the above-mentioned low-pass filter 20 and the output signal of the demodulation circuit 22.

The matrix circuit 23 mixes the above-mentioned direct input signal, a green color signal obtained by demodulating the first modulated color signal, and a green color signal obtained by demodulating the modulated color signal with respective polarities and mixing ratios. Through this process, the desired signals, e.g. B. three do color value signals R, G and B or three color difference signals derived from the matrix circuit 23.

If the three primary color signals are to be obtained from the matrix circuit 23, this circuit is operated in such a way that the output signal of the Us demodulation circuit 22 is subtracted from the output signal of the low-pass filter 20 in the matrix filter 23, so that a blue color value signal is obtained.

The output signal of the demodulation circuit 27 is derived from the output signal of the demodulation circuit 22 subtracted (where '.' I the amplitude ratio of the signals is set to a certain value), to get a red color value signal. The amplitude of the output signal of the demodulation circuit 27 is adjusted so that a green color value signal is obtained.

In the practical implementation of the invention, the first filter strip C1 of the color resolution effecting strip filter 13 be designed so that it the light of any of the three color values of the lets through additively mixed colors. In the case where it is particularly suited to let the blue light through, it is possible to obtain a blue chrominance signal which has a low intensity, and further also to derive the signals of the other two color values in a satisfactory manner and the output the matrix circuit 23 correct color signals can be picked up. A preferred embodiment of the invention is that the first filter strip C1 has the property of blue light to let through.

Further, if it is arranged by means of the optical system so that that of the above-mentioned direct Signal occupied band not by a superposition of the direct signal and the first modulated color signal is occupied, you can have disruptive effects such. B, the occurrence of unwanted crosstalk between the signals of the two bands and avoid interference from beat frequencies.

Another property of this circuit is that the output signals of the matrix circuit 23 directly as they occur can be used as coding input signals, since all output signals of the Matrix circuit 23 are color signals whose bandwidth is limited. In this case it is not necessary to have one Provide low-pass filters in the encoder to limit the band.

Another advantage of the circuit shown in this example is that a particularly simple Structure and manufacture with low costs, since one of the three filter strips is suitable, let white light pass through so that it is a clear strip. Further it is not necessary to provide a device for generating interrogation pulses, which in the usual Color television signal generators are required which operate with the phase separation, and there also a memory and Query operation is not required. is c; possible to have a color television signal with excellent Establish signal-to-noise ratio. Another advantage of this circuit is that it leads to: Color resolution used strip filters readily in the optical system of the camera tube to produce the color signals can be incorporated, since the filter strips have such a spatial position that sii all produce the same spatial frequency.

The invention will now be described in connection with a second embodiment which is described in de Fig. 8-14 is shown.

The stripe fillc effecting the color resolution of this second exemplary embodiment has a pattern, da is shown in Fig.8, with a first filter strip Cl a width a / 4, a second filter strip C2 a Width a / 4 and a third filter strip C3 has a width a / 2, the strips being parallel and close to one another are arranged in the order named, so there

they are a group of a series of identically repeating groups in parallel and side by side Form order. The light transmission properties of the filter strips Cl, C2 and C3 are the same as those of the filter strips Cl, C2 and C3 in the previous example shown in FIG. 2 is shown

The intensity distribution when white light (W) falls on the color-resolving strip filter with the filter strips Ci, C2 and C3 of the width specified above is shown graphically in FIG. The blue

Light (B) is distributed continuously as it is transmitted through all of the filter strips Ci, C2 and C3. The red light has a width of 3 a / 4 with a distance of a / 4, since it is only allowed to pass through the filter strips C2 and C3. The green light (G) has a width of a / 2 and a distance of a / 2, since it is only allowed through the filter strip C 3.

The output signal S of the image pickup tube can

ίο therefore represented by the following Fourier series will:

S =

2SG + SR . SR

sin οι η cos ο /

-τ

SR

- sin

(D

In this equation, the angular frequency ω is the same 2π / 1, and the terms of signal components higher than the third order are omitted.

The first term on the right-hand side of this equation (1) represents direct signals which correspond to the color value signal components SB, SR and SG and has a frequency band which is represented in FIG. 10 by curve IV. The second expression on the right-hand side of equation (1) represents a modulated color signal, which results from the amplitude modulation of a carrier wave of the same frequency as the above-mentioned spatial frequency fi with a mixed signal of the green color value signal (SG) and the red color value signal ( SR), which has a frequency band in FIG. The third expression on the right-hand side of equation (1) represents a modulated color value signal that results from the amplitude modulation of a carrier oscillation of frequency f2, which has twice the value of spatial frequency l \ , by a red color value signal (SR) results and leads to a frequency band in FIG. 10 which corresponds to curve Vl.

If the respective transfer characteristics of the filter strips C1, C2 and C3 are formed similarly to the first embodiment, the blue color value signal (SB) appears only in the direct signal of the curve IV, since blue light is transmitted through the entire area of the strip filter.

If the green color value signal CSGJl which in the Group of filter strips allowed to pass through only one half of the width, as a Fourier equation is expressed, it is found that a high frequency component of an even order does not appear. For this reason, the only even order high frequency component of the spatial frequency is Tinsel the signal component of the red light.

Exemplary embodiments of demodulation circuits for the output signal S of the above-mentioned image pickup tube are shown in FIG. Il and 12 shown.

The output signal S of the image pickup tube 30 is fed to a low-pass filter 31 and band-pass filters 32 and 33 fed. The low-pass filter 31 becomes a direct <«> Signal taken from Volume IV. A modulated color signal is generated from the batid pass filter 32 derived according to volume V. A modulated color value signal is generated from the band-pass filter 33 obtained according to the volume Vl. The direct signal it of the low-pass filter 31 is fed to a matrix circuit 34. The modulated color signal of the band-pass filter 32 is demodulated in a demodulation circuit 35 and, after passing through a Low-pass filter 36 and a band limiting circuit of the matrix circuit 34 mentioned above. The modulated chrominance signal of the band-pass filter 33 is demodulated in a demodulation circuit 37 and then after passing through a low-pass filter 38 and a band limitation of the same matrix circuit 34 forwarded.

The signal fed from the low-pass filter 38 to the matrix circuit 34 is a color value signal of the primary color, the demodulation of the modulated chrominance signal by the third expression of the right Side of equation (1) is shown. That fed to the matrix circuit 34 from the low pass filter 36 Signal is a mixed signal of two color values, which is produced by demodulating the modulated color signal which corresponds to the second term on the right-hand side of the equation (1), i.e. h., it is a Mixed signal from two color values of the low-pass filter. In the matrix circuit 34, the signal of the low-pass filter 38 and the signal of the low-pass filter 36 mixed in a corresponding ratio, so that a other of the color value signals is obtained. By in the matrix circuit 34 in a corresponding ratio a direct signal that contains a mixture of the three color value signals and that of the first expression on the right-hand side of equation (1), extracted from the low-pass filter 31 and with the two Mixing color value signals that are derived in the manner described above, it is still possible remaining chrominance signal. In this way, the three color value signals are obtained from the Matrix circuit 34 derived.

In the demodulation circuit in Fig. 11, the signal component in the form as it is derived from the Amplitude modulation of a carrier wave with a frequency results that is twice the value of the Spatial frequency / "1 corresponds to the filter strip, none large amplitude, so that there may be cases where the signal-to-noise ratio is difficult prepares.

These difficulties can be caused by a Schaltuii: which is illustrated in the embodiment de Fig. 12, the blocks of the circuit which correspond to those of FIG. 11, not yet cinmi explained. The circuit differs from the temporary embodiment because of this that a delay circuit (delay element 39 and an adder circuit 40 before the bandpass filter 33 are arranged.

The delay line 39 has such a delay tion properties that they can speed up the input signal

Time delayed, which correspond to half a period (a / 2) of the spatial frequency f \ , ie a time segment which corresponds to a period (a / 2) of an oscillation: whose frequency is equal to twice the frequency f 1 of the carrier oscillation.

When a signal according to FIG. 13A directly from a Image pickup tube 30 is supplied to an input of the adding circuit 40, a signal which is by one Period (a / 2) equal to half of the period a of the signal of FIG. 13A using a delay line 39 is delayed is supplied to the other terminal of the adding circuit 40. Aud the addition of Signals according to FIG. 13A and F i g. 13B in the adding circuit 40 results in a signal which, for example, in Fig. 14 is shown and that of the following Bandpass filter 33 is fed.

Here the output signal of the adding circuit 40 is obtained, which is composed of the superposition of the red signal SR with a period of a / 2 and a signal (2SB + SR + SG) , ie the sum of a signal 2SB, which is twice the value of the blue signal (SB), the red signal (SR) and the green signal (SG) When the frequency of the carrier wave with the period a / 2 is designated as (2 , where / "2 = 2/1, the red signal takes SR 14 a frequency band VI in Fig. 10. In other words, the signal of the frequency band VI which occurs at the output of the adding circuit 40 is a modulated color value signal which results from the amplitude modulation of the carrier oscillation with the frequency / "2 by the red Signal SR results.

By supplying the output signal of the addition circuit 40 to the band-pass filter 33, a modulated color value signal in the frequency band VI in FIG. 10 is obtained. This signal is demodulated by the demodulator 37, whereby the red color value signal SR is generated. This red signal SR has an amplitude which is twice as large as that of the red signal SR from the demodulator 37 in FIG. 11 demodulator circuit shown. For this reason, the problem of the signal-to-noise ratio of the circuit F i g. 11 eliminated.

The matrix circuit 34 processes the direct signal of the low-pass filter 31, the mixed signal, which is through the Demodulation of the demodulated color signal is taken from the low-pass filter 36 and the above-mentioned red signal, which is taken from the low-pass filter 38 and generates the desired signal at the output with three primary colors or three color difference signals.

By using the color stripe filter of FIG. 8 can be a high level of the direct signal component can be achieved, making this facility even with color television cameras with a single tube can be used well.

Next, an embodiment of the matrix circuits 23 and 34 will be described.

When the output signal S of the first embodiment shown in FIG. 5 by a Fourier series of equation (1) is expressed as follows:

S =

/ 2SR + SG - {· sin int

SG

- COS o> f I -

(2)

If on the right-hand side of equations (1) and (2) the first, second and third expressions are drawn with SO, S1 and S2, then the direct signal SO is a mixed signal of three color value signals, while the modulated color signal S1 is a signal of one Shape is. which results from the amplitude modulation of a carrier oscillation of the spatial frequency f \ by signals of the two color values which differ from the color value which is let through by the first filter strip C1 of the strip filter. The modulated color value signal S 2 is a signal of such a form that results from the amplitude modulation of a carrier oscillation of a frequency with the value fl , which is equal to twice the value of the spatial frequency f \ , by modulation with the signal of a single color value, the remains after the other two color values have been eliminated, namely the color value of the light which is transmitted through the entire surface of the strip filter and the other color which is transmitted by the strip filter over half the width.

An exemplary embodiment for the matrix circuit 23 and 34 is shown in the block diagram of FIG. 15 shown. This circuit includes three inputs 50, 51 and 52 to which the above-mentioned direct signal SO and a, respectively demodulated signal SId of the demodulated color signal Sl and the demodulated signal S2d of the demodulated color signal S 2 are supplied. t> s

If the strip filter has the structure according to FIG. 2, the signals SO, SId and S2d correspond to the Inputs 50, 51 and 52 are fed to the following conditions:

2 ⁺ 4

(3)

\ (2SR + SGf + SG *

SId ^ ^

(5)

If, furthermore, the filter corresponds to the one shown in FIG. 8 shown Structure, the signals SO, S Id and S2d correspond to which are fed to terminals 50, 51 and 52, the following equations:

SO =

SU = -

ISG SG

1 (2SG + SRf + SR ²

(6)

(7)

CD

SId = -

Γ7

The signal S 2c fed to the input 52 is multiplied by the factor π in a circuit 54 and therefore converted into a color value signal that is fed to an output terminal 66 on the one hand and on the other hand

The signal S id at the input 51 is multiplied by the value π in a circuit 53 and passes through an exponentiation circuit 54 and is fed to the above-mentioned subtraction circuit 57 as a minuend.

The output of the subtraction circuit 57 is used as a minuend of a second subtraction circuit 59 is fed through a square root circuit 58. The output of the circuit 54 is given as Subtracted to a second subtraction circuit 59. As a result, the other chrominance signal, which forms the mixed signal of two color value signals, taken from this subtraction circuit 59. The output signal of the subtraction circuit is halved in a circuit 60 and appears at the Output terminal 65.

The signal, which is mixed from the three color values and is available at input terminal 50, is called Minuend fed to a third subtraction circuit 63. The color value signals at the output terminals 66 and 65 are adjusted to the required amplitude with the aid of the adjustment circuits 61 and 62 supplied as subtrahends to the subtraction circuit 63. At the output of this third subtraction circuit 63 the remaining color value signal occurs, which is taken at output 64. At the output terminals 64, 65 and 66 are therefore perfect signals of the three color values available.

When reproducing the signals in the example given above, an exponentiation circuit, a subtraction circuit, a square root circuit are used together with other switching elements in order to. to form the mixed signal S id of the two color values, which corresponds to equations (4) and (7), which is fed to the input 51. The desired signals can also be obtained by approximating the mixture SId of the two chrominance signals with a first-order equation representing the two above-mentioned equations and applying them to a matrix circuit with the other two kinds of signals.

If the three color value signals are designated PCI, PCI and PC3 and the corresponding expressions are used for the three signals SO, Sid, S2d , then equations (3), (4) and (5) can be converted into equations (3a ), (4a) and (5a) can be written:

SO = PCl +

PC3

SId = PC3

(3a)

(4a)

(5a)

Equations (6), (7) and (8) can also be rewritten in a similar manner by appropriately choosing the coefficients λ and β so that the above equation (4a) is approximated by a first-order equation, which is represented by is linked to the two color value signals PC2 and PC3, the signal S l </ can be expressed as follows:

SXd = χ PC2 + Ii PO (4al)

The signal of this equation (4a t) and the signals of the above equations (3a) and (5a) become one Matrix circuit supplied in order to obtain the desired signals at the output of this matrix circuit. A third embodiment for a device according to

S of the invention is described in connection with FIGS. 16, 17 and 18. As shown in Fig. 16, the color stripe filter of this apparatus includes a Number of groups of filter strips in parallel and in adjacent arrangement, each group consisting of

ίο a first, second, third and fourth strip is composed, which are designated with / 1 to / "4 and are arranged in parallel and adjoining each other all with the same width of a / 4.

The properties of the filter strips in terms of permeability are as follows:

The first filter strip F1 lets through the light of a color value that corresponds to the three color values of the additive color mixing. The second filter strip F2 lets through the light of a mixed color that the primary color of the first filter strip Fl and one corresponds to the other two color values. The third filter strip F3 lets the light of a mixed color through, which corresponds to the first color value of the first filter strip Fl and the color value which of the Filter strip F2 is not allowed through. The fourth filter strip F4 lets the light of all colors through.

In particular, the second and third filter strips F2 and F3 are designed so that depending on the color value, ie blue light (B), green light (G) and red light

(R) which is let through by the first filter strip Fl, they let through the light of the other colors according to the following table:

Color of the Fl Color of the F2 Color of the F3 35 let through let through let through Light Light Light B. C. M. B. M. C. % o G C. Y G Y C. R. Y M. R. M. Y

In the table, the colors are denoted by the following letters: B = blue, G = green, R = red. C = cyan blue (a mixture of the colors blue and green), M = magenta red and Y = yellow (a mixture of the colors green and red). An example of a color strip filter with filter strips of the combinations given above corresponds to the combination given in the first line, i. The first filter strip Fl lets through blue light, the second filter strip F2 lets the light of a mixture of colors (cyan) of blue and green through; the third filter strip F3 allows a mixed color (magenta) of blue and red to pass through, and the fourth filter strip F4 allows a mixed color of blue, red and green to pass through, ie light of all colors or white light.

If white light falls on a color stripe filter which contains this combination of color stripes, then the intensity of the light corresponds to the diagram in Fig. 17, in which blue light (B) differs from the whole! Area is transmitted, green light (G) is present with a width of a / A , red light (R) extends it! over a width of all and green light (G) is present with a stripe with the width a / 4.

The output signals received from an image pickup unit

re 70 can be generated, which is equipped with a color stripe filter of the type just described can be expressed by the following Fourier series:

SG. . _t
· Sin 2o> t

2SR

sin does

(9)

The first term on the right-hand side of equation (9) represents a direct signal resulting from the color widths SB, SR and SG . The second term represents a first modulated color signal.

which results from the amplitude modulation of a carrier wave of the same frequency as the spatial frequency / la, which is determined by the number of groups of filter strips / 1 to / 4 in the red signal. The third expression represents a second modulated color signal which results from the amplitude modulation of a carrier wave with the frequency / 2a, which is equal to twice the value of the above-mentioned spatial frequency / 1 a by the green signal.

For the demodulator circuit of the above-mentioned output signal S , an arrangement ζ B. shown in Fig Π can be used. The color stripe filter of Fig. 16 is very easy to manufacture because all of the filter strips have the same width (a / 4).

In addition 5 sheets of drawings

Claims (4)

Patent claims: 1. Device for generating color television signals with an image pickup tube fitted with a color strip filter on its front is, which has a number of groups of filter stripes which are successively repeated in sequence, each group including a first filter strip that is transparent to light is designed so that it lets through the light of one of the three color values of an additive color mixture, a second filter strip containing at least a portion of such light transmission has that it is the light of a mixed color from the color value passing through the first filter strip passes through, and one of the other two color values passes through, and a transparent third Contains filter strip that transmits white light, the first, second and third filter strips are arranged parallel to one another and adjoining one another, the image pick-up tube being a Output signal is generated that is superimposed on a direct signal, a first amplitude-modulated Color signal with a first carrier frequency and a second amplitude-modulated color signal with a contains second carrier frequency, further comprising a first separation circuit, the direct signal from the The output signal of the image pickup tube is separated, a second separation circuit, the first amplitude-modulated Separates color signal from the output signal of the image pickup tube, and a third separation circuit the second amplitude modulated color signal from the output of the image pickup tube separates, in which further a first demodulation circuit, the first amplitude-modulated color signal demodulated after the separation, and a second demodulation circuit the second amplitude-modulated Color signal demodulated after separation, and with a matrix circuit connected to the outputs of the first isolation circuit and the first and second demodulation circuit and the desired output signals of the three color values or the three difference colors generated, characterized in that two of the three filter strips have the same width and the third filter strip has a width which is twice as large as that of the other two strips, so that the second carrier frequency is twice the first carrier frequency that the third separation circuit a delay circuit (24,39) contains which the output signal of the camera tube by half Period of the first carrier frequency delays that an adding circuit (25, 40) the output signal the image pick-up tube and the delayed output signal of the delay circuit are added, and that a band pass filter (26,33) is responsive to the output of the adder circuit and passes the second amplitude-modulated color signal from the output signal of the adder circuit. 2. Device according to claim 1, characterized in that the second filter strip (C2 in F i g. 2) and the third filter strip (C3 in Fig.2) have the same width (~ J and that the first filter strip (C 1 in Fig.2) has twice the width f yj as the second and third filter strips. 3. Device according to claim 1, characterized in that the first filter strip (C 1 in F i g. 8) and the second filter strip (C2 in Fig.8) the same width (4-) and the third filter strip (C3 in Fig. 8) twice the width (y) as the first and second strips 4. Device according to claim 1, characterized in that the first filter strip (F 1 in F i g. 16) and the third filter strip (F 4 in Fig. 16) the same width f 4-! and the second filter strip (F2 plus F3 in Fig. 16) has twice the width of the first and third filter strips, so that the second filter strip has a first part (F2 in Fig. 16) with such a light transmission characteristic that it receives light of one of the color values transmitted by the first filter strip and one of the two other color values mixed color, and a second part (F3 in Fig. 16) which has such a light transparency that it transmits light of one of the color value of the first filter strip and the color mixed from the other of the two color values, the first and second part consists of parallel strips of the same width as the first and third filter strips.