DE1946199A1 - Color television set - Google Patents

Description

33/74 September 9, 1969

PATENT LAWYERS

DR.-ING. WOLFF, H. BARTELS, Reg. 122 093

DR. BRANDES, DR.-ING. HERO

7 STUTTGART-N, LANGE STRASSE 51

EASTJyIAN KODAK COMPANY, Rochester, New York State, United States of America

Color television set

The invention relates to a color television set with two recording devices, the first of which receives the luminance information and the second the color information.

The known devices of this type have the disadvantage of a poor color accuracy afflicted by what is lacking Synchronization between the amplitude changes of the color signals and the luminance signals is conditioned. To this one To avoid the disadvantage, the color television recording devices customary today have three recording tubes, of which each is sensitive to one of the three primary colors. But here too there are problems because the images of the three pick-up tubes must exactly coincide. If there is no exact coverage, there will be a disruptive one Color fringing.

Solutions for eliminating these difficulties are known. For example, in U.S. Patent 2 733 291 describes a recording device with a single

009818/1241

umpteen image pickup tube and some kind of parallel working Multiple-exploitation works. A beam splitter divides the light beam into three parts and filters these parts so, that each partial beam contains only one of the three basic colors. Each partial beam is then passed through a grid that have different spatial frequencies. Then the partial beams are projected back onto the image pickup tube. The output variable of the image pickup tube is therefore composed of three different frequencies. Spicy Matched filters separate the three frequency components so that each color component forms a continuous one Color signal can be integrated. The luminance signal is generated by a combination of the three color components generated. The disadvantage of this device is that a pickup tube with a very high resolution is required to keep the grating frequencies true to be able to reproduce. The price of such image pickup tubes is so high that it is significantly cheaper, two Image pick-up tubes with lower resolution too use. .

The invention is based on the object to create a Farbfernsehaufnahr.gerät that is cheaper than dieje-. Nigen devices with a single camera tube _high: resolution but in Gegenstatz to the devices with two camera tubes gives good color accuracy.

Starting from a device with two recording devices of the type mentioned at the outset, this object is achieved according to the invention in that the second receiving device Generates signals with variable levels that contain luminance information in addition to color information,

0 09016/124 9

-% $% original; · - ■.

.194BI

and that a comparison device, which the corresponding luminance signals of the two recording devices compares and generates an output variable representing the difference between these signals, as well as a gain control is provided which the Level of the color information signals as a function of the output of the comparison device controls.

The two recording devices can have a relatively low resolution without the image quality suffers. The synchronization is through the control of the level of the color information signals. ensured as a function of the output variable of the comparison device.

In a preferred embodiment, the receiving device takes only two basic colors for the color information on. The third basic color is derived from the Leucltdich te signal by subtracting the two color signals.

If an even more exact synchronization of the luminance signal with the color signals is desired, this can be done with a Second recording device can be achieved, which records the color information of all three basic colors. the three color signals v / earth then combined to form a luminance signal low resolution with which the luminance signal high resolution that the first recording device he testifies, is controlled in order to keep this in exact synchronization with the color signals or vice versa bring. The even better synchronization and the resulting better color accuracy are, however, with a Reduction of the resolution linked.

009816/1249

The invention is explained in detail below with reference to two exemplary embodiments shown in the drawing.
Show it:

Fig. 1 "is a plan view of a part of a mask for a color pick-up tube that picks up the color information of two basic colors,

Fig. 2 is a plan view of part of a mask for a color pick-up tube that contains the color information picks up all three primary colors;

Fig. 3 is a block diagram of a first embodiment of a color television recorder with a two-color recording device,

Fig. 4 is a block diagram of another off - .. ■ "." management example with a three-color recording device.

In a color television system, one color picture becomes four Sizes defined. These four quantities are the luminance and the intensity or color saturation of each of the three primary colors. However, only three of the four variables need to be known in order to be able to transfer all information, because the luminance is equal to the sum of the three quantities for the individual primary colors. A complete Color image, therefore, can be generated on the basis of information that is the color information of two Basic colors and the luminance information contains »The Information for the third basic color is obtained by subtracting the color signals of the two basic colors from Luminance signal.

0098167124a

ÖÄ &

In a first embodiment, a mask is as shown incompletely in Fig. 1, in front of the front surface of a monocromatic television pickup tube arranged. The recording camera is of such a known type, specifically one in the exemplary embodiment Vidicon camera. But it could also be a plumbicon camera or an Orthicon camera can be used. The embodiment is with a vidicon camera equipped because it is the cheapest. The mask shown in FIG. 1 has groups of two different stripes Colors on. Group 1 consists of alternating clear and yellow stripes, whereas group 2 insists on alternating clear and cyan stripes. the the two groups are separated in the exemplary embodiment by clear strips 3, which, however, are also omitted could. The spatial frequency of the "blue" controlling stripe group 1 is different from the spatial one Frequency of the "red" controlling stripe group 2. Contains the output size of the mono :: romantic recording camera therefore a frequency component with the blue information and a frequency component including the red information. The clear areas give a low frequency component or a DC voltage component containing the luminance information.

Since a much higher resolution is required for the luminance signal than for the color signals, a separate resolution is required Pick-up tube provided for generating the luminance signals. This pickup tube is natural not provided with a mask. .

009916/1243

BATH

Fig. 3 shows the block diagram of the embodiment . A first monocromatic recording camera 4 is unmasked and therefore receives all of the light on the basis of which it generates luminance signals. The output size of the recording camera 4. becomes a Amplifier 5 is input, which a luminance density signal Y generated. The luminance signal Y is fed back via an automatic gain control β to a Signal for a constant luminance effect.

A second mono :; romantic recording camera 7 is with a mask according to that in Fig. 1 provided in front of its photosensitive surface. The output size of the Recording camera 7 is fed to an amplifier 8. The output of this amplifier 8 becomes simultaneous to a low-pass filter 9 and a band-pass amplifier 10 given.

The low-pass filter 9 allows the DC voltage and very low frequency components of the output of the recording camera 7 to pass, which correspond to the luminance component of the signal. Since this luminance component of the signal has a lower resolution, it is marked ^{with Y 1.} This luminance signal Y "is fed to a differential amplifier 11, at the other input of which a second luminance signal of low resolution is applied, which is derived from the luminance signal Y of high resolution, identifying the luminance signal Y through a low-pass filter 18 is led "the output of the Differenzverstär3 £ @ rs il is an automatic gain control 12 of the Färbinformationen receiving 'camera 7 zn surückgefühtty * m a constant velocity

between this recording camera and the recording camera for the luminance effect.

The task of the bandpass amplifier IO is to the luminance component of that of the recording camera to separate the generated signal and to suppress high-frequency interference signals. The output of the bandpass amplifier 10 arrives at. "two narrow bandpass filters 13 and 14. The bandpass filter 13 lets that frequency component through which corresponds to the red signal, while the bandpass filter 14 the signal component which corresponds to the blue signal corresponds, lets through. The red signals and blue signals are then filtered by means of a demodulation filter 15 · or 16 amplitude demodulated. The green signal is generated by having the red signal, the blue signal and supplies the leucli density signal to a matrix 17. the Matrix 17 subtracts the red signals and blue signals from the luminance signal. The determined The green signal represents the difference.

The high resolution luminance signal Y and the color signals relatively low resolution are used here of two monocromatic recording cameras with relative low resolution.

With some types of pick-up tubes, the sensitivity is lower for low-frequency signals different from the sensitivity for high-frequency signals. When the color signals and the luminance signals are generated by two different recording cameras * one would in this case have a different sensitivity for the luminance signal than for the color signals. The one shown in FIG Embodiment can be used together with that shown in FIG Mask to overcome this difficulty.

009 818/1249

D ORIGINAL

The mask shown in Fig. 2 is designed similarly like that according to FIG. I, however, also owns a third group of strips 119, which alternately, successive clear and purple stripes exists' and generates a green signal. With the help of this mask, all three color signals can be used independently generated by the luminance signal. ■

The circuit of the second embodiment shows 4. A recording camera 104 for the luminance information is designed and generated like the camera 4 of the exemplary embodiment according to FIGS. 1 and 3 in a similar way to this a luminance signal Y. A color camera 107, which differs from the camera 7 only in that she wears the mask according to FIG. 2 instead of the mask according to FIG. 1, takes up three high-frequency components. Each of these three components represents a color component. The color signals pass from the color camera 107 to a bandpass filter 120, which filters out interference signals. Then the color signals in a video amplifier 121 is input from which they go to filters 122, 123 and 124. Any of these three The filter is tuned to "the frequency of one of the three color components, so that only the signals that the associated color are assigned to demodulators or 26 and 27 respectively. The output size of the demodulators are the green signals or the red signals and the blue signals. The output variables the demodulators are also in a matrix input, which adds the color signals to get it

0 9816/1249

to generate a luminance signal Y ^{1 of} low resolution. The luminance signal of the recording camera is passed through a low-pass filter 129 in order ^{to generate a second luminance signal Y 'e of} low resolution. These two luminance signals are fed to a differential amplifier 130, the output variable of which is fed back to the video amplifier 121 in order to regulate its gain.

Since in the embodiment of FIG. 3, the gain of the color camera 7 by using the High resolution luminance signal from the luminance recording camera 4 is generated, regulated, the DC voltage component of the color camera Generate errors if .the color camera is a different one It is more sensitive to the DC component of the color signals than to the high-frequency color components. The embodiment according to FIG. 4 however, conducts the low-resolution signal directly from the high-frequency color signals. Therefore, the gain of the color signals depends on the High frequency sensitivity of the color camera instead of depending on the DC voltage sensitivity controlled.

The masks shown in Figures 1 and 2 have separate groups of strips. Of course it could each group of strips also cover the entire mask In this case, the groups of stripes could be stacked on top of each other as described in U.S. Patent 3,364,497.

009316/1249

QfHGJNAi.

Claims (1)

P a t en ta η proverbs Color remote control device with two recording devices, of which the first records the luminance information and the second records the color information, characterized in that the second recording device (7,107) generates signals with variable levels which, in addition to the color information, also include luminance information and that a comparison device (11, 130) which compares the corresponding luminance signals (Y, Y ^{!; Y 1} , Y ¹¹ ) of the two recording devices (4, 7-104, 107) and generates an output variable representing the difference between these signals , and a gain control (12, 121) is provided which controls the level of the color information signals as a function of the output variable of the comparison device. Apparatus according to Claim 1, characterized in that the second receiving device (7) is a device (9,10,13 to 16) to generate the color information containing high frequency signals and the Leuehtdiehte information containing low frequency signals. 3k device according to claim I, characterized in that the second recording device (107) has a device {22 to 28) for generating high-frequency signals, which has both the color information and the light density "information ehth & Xte &v" BADORJGiNAL Device according to one of Claims 1 to 3, characterized by a mask (1, 2, 3) in front of the second receiving device (7) with a strip (1)
first color and first spatial frequency as well as stripes (2) of a second color and second spatial frequency and a matrix (17) which is connected to the two recording devices (4,7) and which derives signals containing the color information of the third color from their signals. 009818/1249