DE966569C - Method for generating color television signals - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

ISSUED AUGUST 22, 1957

GERMAN PATENT OFFICE

PATENT LETTERING

CLASS 21a ¹ GROUP 34 si INTERNAT. CLASS H04n

E 8365 VIII al 2i a>

Ivanhoe John Penfound James, London

has been named as the inventor

Electric & Musical Industries Limited, Hayes, Middlesex

(Great Britain)

Method for generating color television signals

Patented in the territory of the Federal Republic of Germany from January 1, 1954 Patent application known since November 8, 1956

Patent issued August 8, 1957

The priority of filing in Great Britain January 2 and December 22, 1953

is used

The invention relates to the generation of color television signals.

In an essay entitled “Specifications

for Color TV Field Tests ", in" Electronics ", January 1952, is the composition on p. 126 of an image signal wave train used for color television is suitable, described. As pointed out in this paper, the signal voltage persists through

the carrier wave for broadcasting the television

signals is modulated, from a brightness signal

(e.g. F) representing the mixed color intensity of the optical image, and two color difference signals B - Y and RY, respectively, where B means signals representing the intensity of the blue component of the image !, and. R means signals that represent the intensity of the red component of the image.

The one in the above. The bilas signal wave train described in the article is "tolerable"; H. suitable for direct viewing by both black-and-white television receivers and by Color television receiver.

709 641/19

The shape and the production of the above-mentioned wave train are nevertheless relatively complicated. The purpose of the present invention is to provide a relatively simple process and to provide an apparatus which can produce simultaneous color television signals of the type described above or other color television signals related to it.

According to the present invention, from

ίο a pickup tube signals the intensity of mixed colors of an optical image, are obtained from a second Pick-up tube signal elements obtained in a time sequence, which have the intensity of only two represent different color components of elements of the same optical image, and the output voltages of the two 'pick-up tubes combined to receive color television signals the three color components of this optical picture

ao can be obtained !.

To carry out this process, a device for generating color television signals is provided, containing two pick-up tubes for simultaneous exposure to an optical image, wherein

the first pickup tube has a signal output voltage evokes the intensities of being mixed. Colors of the image, and the second pick-up tube generates an output voltage containing signal elements in time sequence,

which represent the intensity of only two different color components, of elements, of the picture, and further comprising means for combining the output voltages of the pick-up tubes to generate color television signals.

In order to generate the signal elements, the different color components in the output voltage, which is obtained from the second pick-up tube, represent in time sequence, is a color filter for filtering the light that is thrown onto the second pick-up tube, wherein the color filter preferably strip-shaped filter elements of the two colors with opaque or transparent elements between successive i Groups of. two colored

Contains elements. The opaque or translucent elements are connected with a suitable bias light is used to generate tactile signals that on a separate amplitude range., outside of the color signal elements are limited in the output voltage of the corresponding pickup tube where the key signals can be used to convert the color signal elements into their appropriate To feel channels.

The invention will now be made with reference to the drawings which illustrate an exemplary embodiment represent, described in more detail,

Fig. Ι shows schematically and mainly in block form an example of an embodiment Device for generating color television signals! according to the present invention;

Fig. 2 shows a fraction of a color filter that is used in Fig. Ι, again;

Fig. 3 is a schematic block form of an apparatus for forming color difference signals from the Output of Fig. 1 again;

FIG. 4 is a modification of FIG. 2.

In the drawing, a device for generating color television signals is shown, which contains the two pick-up tubes 1 and 2 of a known type. An optical system comprising a lens 3 and an image splitting device 4 is provided to simultaneously focus images of the television scene onto target electrodes of tubes 1 and 2, these target electrodes being designated by reference numbers 5 and 6, respectively. A color filter 7 is arranged close to the target electrode of the tube 2, the plane of the filter 7 being parallel to the target electrode. Part of the color filter 7 is shown in Fig. 2 and, as indicated herein, the filter contains groups of three stripes arranged in cyclic order, each group having an opaque stripe y _a , a translucent blue stripe, y _b and contains a translucent red stripe y _c . The strips extend at right angles to the line scanning direction in the tube 2. A lamp is also provided, which is intended to illuminate the mosaic screen 6 with white light through the colored strips, so. that the black level for the pickup tube is raised 2 x. The signal output of the tube 2, which corresponds to the opaque stripe in the filter, then takes the form of blacker-than-sch.wa.rz impulses which, as will be seen later, are used to convert color signal elements into suitable To feel channels. Further, a is filter provided in front of the mosaic screen of the tube 1, said filter having a suitable characteristic to the mixed color signals which are generated by these up ioo transfer tube, the Signalen- Y of the aforementioned composite color signal corresponding to lassem

The signal output voltage of the tube 1 is fed to a suitable amplifier, which is shown in Block shape is indicated at 10. In; similar way the signal output voltage of the tube 2 is fed to an amplifier 11. The latter output voltage contains signal elements, which - alternately the intensity of the red and blue no Components, of elements of the optical image, with each group of signal elements, preceded by a blacker-than-black pulse. The output voltage of the amplifier

11 is simultaneously a limiter 12 and Passages 13 and 14 fed. The limiter

12 removes the color signal elements, with the negative tactile pulses, which over two delay networks 15 and 16 are guided to the passages 13 and 14, respectively, remain. The delay of the network 15 is such that the passage 13 only occurs during the occurrence of "blue." SignalelementetL in the output of the tube 2 open will while the delay of the network

16 is such that the passage 14 is only during this _ir .s occurrence of. »Red.« Signal elements in the

passage of the tube 2 is open. As a result, after suitable smoothing, the passage 13 becomes a continuous sequence of. Signals obtained representing the blue component of the optical image, the is focused on the mosaic screen 6, while of the passage 24 is a permanent

E _m = E _v sequence of signals representing the red component of an optical image is obtained.

FIG. 3 shows a circuit for obtaining, from signals as can be obtained from FIG. 1, a composite color image signal E _m which is expressed by the equation

1.14 \ i, 78 - E _v ) sin mt + (Er - E _y ) cos cot

is pictured. Herein, E _{y represents} the luminance signal received from the tube 1, E _B and E _R represent the outputs of the passages 13 and 14, and ω the angular frequency of a color difference subcarrier. The voltage E _y from the amplifier 10 passes through a delay compensation circuit 17 and corresponds to the signal which is designated Y above. As stated above, the filter 9 has a transmission characteristic which is selected in connection with the spectral sensitivity of the pickup tube 1 in such a way that the output voltage represents the brightness of the optical image. After amplification and smoothing, the output voltage of the passage 13 runs, if necessary, via a delay compensation circuit 18 to a matrix which is mainly represented by the dashed outline 19. The matrix contains a subtraction circuit 20 which receives the input voltage from the circuits 17 and 18 and an output voltage; ZT ₈ - Ey generated. This difference signal v.- ^: rd dan ;; led to an amplifier 21, the gain of which is proportional to the number constants

· —- in relation to the signal Ey that

1.14 1.78 ^{& Y}

is obtained from circuit 17 is. The output voltage of the amplifier is consequently a color difference signal, as indicated above with B - Y. The output voltage of the passage 14 goes to a delay compensation circuit 22 and from there to a differential circuit 23 in the matrix 19. The circuit 23 also receives an output voltage from the circuit 17 and produces an output voltage E ^ - Ey. This output voltage is amplified in the amplifier 24, the amplification of which is chosen so that E ^ - - Ey with the number factor

is multiplied, thereby producing a color difference signal corresponding to the above R - Y. The delay compensation circuits 17, 18 and 22 compensate for the time delays in the various amplifiers and cables so that the signals Y, B - Y and R- - Y appear in the correct time ratio for the superposition. The color difference signals from the amplifiers 21 and 24 can then be used to modulate two subcarriers, represented by sincoi and cos cui. The desired composite image signal voltage E ^ is then obtained by adding the signal Y to the modulated subcarrier signal. The frequency

1.14

of the resulting subcarrier may be inside or outside of the band represented by the holiness Esignlail Y. As described above, the voltage E _{M is of the} same type as. the NTSC color picture signal, although in the latter signal the voltages corresponding to E _Y , E 3 and E% are gamma corrected voltages;

In practice, the blue and red signals represented by the voltages Eg and E% only need to have a relatively narrow bandwidth, of the order of 2 MHz or less, and can therefore be used. the strips of the color filter 7 can be ^{wide according to FIG. 1} , so that difficulties associated with the manufacture of the color filters are substantially reduced.

The scanning linearity in the two recording 9 <? tubes 1 and 2 can, if necessary or desirable, by comparison, the negative Synchronization pulses in the output of the tube 2 at the frequency of an oscillator with a constant frequency and use any difference to Correction of the scanning wave trains are maintained.

Instead of the use of opaque strips in the color filter 7, a precise keying of the color signal elements in the appropriate. To secure channels, transparent strips can be used in conjunction with a light source emitting bias voltage in such a way that whiter-than-white tactile pulses corresponding to the transparent strips can be generated. It is also possible to use other aids which are restricted to an amplitude range which is separate from the color signals, for example: two toothed output electrodes can be used in the pick-up tube 2. This modification is shown in FIG. 4, in which one output electrode is indicated by the reference numeral 26 and the other by the reference numeral 27, 27. Each electrode contains a system of interconnected strips which run parallel to the 'strips of the' staining filter and each is as wide as two stripes. J _b and y _c (one blue and one red) of the color filter. In. reality, the color filter can be on the. stripe of the output electrodes. With this arrangement, the output voltage of the color signal elements is alternately A light source !, which: outputs a bias voltage, is used to raise the color signal elements that are generated so that the output voltage from the other Au output electrode (this is the

Electrode from which at a given time no exit from. Signalelemieiiteni is obtained) can be treated as if blacker-than-black pulses exist, and can be used for tactile purposes.

Although the invention in its application to the pick-up tube of the type with photoelectric emitting target electrode is described, so the invention can also using of pick-up tubes with photoconductive target electrodes. It can also a light spot scanner of the pickup tube !! can be used, with simultaneous sampling in two tubes is carried out in that the image of a scanning spot that appears on the fluorescent screen a single cathode ray tube is generated on the target electrodes of both pick-up tubes, is thrown. In this way, the electron-optic decoration problems can be avoided be reduced.

Claims (5)

Patent claims: i. Method for generating color television signals, characterized in that signals are received from a pickup tube, which represent the intensity of mixed colors of an optical image and. that of one second. Pick-up tube signal elements in. Timing will be won · showing the intensity of only two different; Color components of elements of the same optical Picture and that the output voltages combined from the two pick-up tubes to obtain color television signals ^ from which three color components of the optical Image can be obtained. 2. The method according to claim 1, characterized in that diaß the signal elements, which represent one of the two color components, from the signal element, the other of the two Represent color components, and that also the signal elements that each of the Color components represent subtractive with the signals representing the intensity of the mixed Colors of the image are combined so that two sets of fair difference signals i be generated. 3. Apparatus for carrying out the method according to claim 1, characterized in that that two pick-up tubes: for simultaneous exposure through, an optical image are available, wherein the first pickup tube generates a signal output voltage having the intensity of represents mixed colors of the image, and the second pickup tube provides an output voltage generated, which contains signal elements in time sequence, which the intensity of only two different Show color components of elements of the image, and. that funds are also available are to determine the output voltages of the pick-up tubes for generating Fa, rbdifferenzsignen, to combine. 4. Apparatus according to claim 3, characterized in that means are present to the signal elements, which represent two color components, in separate channels separate, and further means for subtracting the signal elements in each of the separate channels to combine with signals obtained from the first, pickup tube, so that two sets of color difference signals are generated. 5. Apparatus according to claim 3 or 4, characterized in that a. Color filter available is to filter light thrown onto the second pickup tube., wherein the color filter contains strip-shaped filter elements of the two colors with opaque or transparent colorless elements between successive groups of two colored elements, and. that further means are present to the signal elements that the above two colored. Filters.treifen correspond to with the help of impulses in the output of the second pick-up tube, which make the opaque or clear colorless elements to be felt in separate channels. 1 sheet of drawings S «09 706/150 10.56 (70» 641/19 p. 57)