DE1537423B2 - COLOR TELEVISION RECEIVER WITH A BEAM INDEX TUBE - Google Patents

Description

1 2 ■■■■■■:

In the case of color television receivers with a beam index, in the different figures denote the same

In the cathode ray tube, reference numerals are used to refer to the same parts.

The screen 14 of a cathode ray tube 12

painted and the when swept over the index strip has an outer surface 16 and an inner

generated index signals are used to synchronize 5 surface 18. The inner surface 18 of the screen

of the color signals with the coating of individual color 14 the cathode ray tube 12 carries several par-

segments of the screen. If a color signal is »zero«, allele, horizontally always next to one another in the same sequence

then the cathode ray is interrupted and vertically extending strip segments are arranged there

with the generation of index signals below 20, 22, 24 (Fig. 1).

broke. As a result, the synchronism can be broken. Each of the segments 20, 22 and 24 generates a

be lifted. light signal of a different color when it is

The invention is based on the object _{: the} beam is hit. Multiple index elements 30 to prevent interruption of the generation of index signals are on the inner surface of the aluminum; In the case of solving this problem, the layer 28 is arranged. The index elements 30 are distributed invention by a-USA. patent by 15 uniformly, vertically extending stripes, 2,837,687 acquaintances color television receiver of which on the cathode ray tube are horizontally spaced from one another several signalerzeu _r surface of the Aluminhmischicht 28
The colored groups of three of the segments 20, arranged in a certain ratio along a line 22 and 24 are in equal proportions and are distributed in a horizontal line with several elements generating an index signal. Also the index elements, which along the same line in segments 30 are distributed in a certain constant one of both the ratio of the groups and the ratio along the line. The relationship between the distribution of the segment groups 26 and the distribution ratio, which deviates from the ratio of the segments, and the one in which the index elements 30 are arranged along the line is important for the density control circuit of the cathode ray tube possessed by Neten limiter. According to the invention, the limiter necessary for the generation of different colors is designed so that it prevents an interruption in intensity changes and phase changes in the cathode ray when the luminance of the scanning ray drops below a predetermined level. can.

This causes an interruption in generation 30 F i g. 2 shows the index signal that is generated by a channel

avoided by index signals. method beam of constant current is generated, the

An embodiment of the invention is in which is moved along the horizontal line and after-

Drawing shown. It shows each other segments 20, 22, 24 and the index

F i g. 1 is an enlarged view in section: through 'elements 30, which are arranged along this line,

a portion of the screen of a cathode ray tube 35 is energized. When the cathode ray left to

according to the invention, right along the horizontal line with a con-

F i g. 2 is a diagram illustrating the constant speed being moved then

Index signal that generates signal peaks 32 one after the other as soon as the

is generated, the beam hits an index element 30. ^;

Fig. 3a shows a diagram to illustrate the modulus 40. Fig. 3a shows the changes in amplitude of the

lation of the beam current for the reproduction of the color cathode ray current as a function of time

Red, ,· ;,-.; ·, .. ■. ... for generating the rendering of a red color.

F i g. 3 b a diagram to reproduce the index The peaks of the cathode ray current occur in a

signals which from the cathode ray for the how- time which the excitation of the red phosphorus delivery the. Colour. Red is generated,. . 45 segments 20 of the groups of three 26 causes.

F i g. 4 a the modulation of the cathode ray for According to the diagram of Flg. 3 b will be

rendering the color green, largest index signal peaks 38 generated when the peak

F i g. 4 b is the index signal that is generated by the cathode 34 of the cathode ray current with a peak 32 ray for the reproduction of the color green generates the index signal meets. The produced waste, . '.-. Λ-: 5ο. Gears of the largest peaks 38 and the small peaks

F i g. 5 a shows the modulation of the cathode ray current 40, which occurs in the region 36 of the cathode ray current

mes for the reproduction of the color blue, produce an output signal with a '

F i g. 5b is the index signal from the basic cathode component indicated by the dotted line

Beam current for the reproduction of the color blue- 42 is indicated. The fundamental oscillation 42 has a is, .:> :: ■: '. ";] - /. ■ ·. ■' :: 55 frequency and a phase which is identical to the

F i g. 6 shows an enlarged illustration in section of the frequency and the phase of the index output signal, a portion of the screen of the cathode ray tube shown in FIG. 2 for the constant cathode ray switch to the left of the in FIG. 1 shown part of the stream is shown.

Is arranged screen and from the cathode ray The in F i g. 4 a shown course of the cathode to The beginning of each line is scanned before scanning 60 the beam current required for the reproduction of the color green

of the in FIG. 1 shown part of the screen, shows peaks 44 of the current only when

F i g. 7 shows a diagram for reproducing the index - green phosphor segments 22 are swept over. the

signal which is generated by the cathode ray when the resulting largest peaks 46 of the generated

flow of the in F i g. 6 are shown in FIG. 4 b reproduced. None mes is generated, 65 of the index elements 30 coincide with green ones

F i g. 8 in block form a color television system, wel- phosphor segments 22. An index element 30 enters

ches the index generating device according to the invention of the first group of three 26 later, while the

used. others in the second group of three 26 earlier

3 4

occurs. Therefore, the peaks 46 of the main index signal 84 come, excited and provide output signals

With respect to the peaks 44 of the cathode ray current, 2 times the value of the triple frequency

mes offset. The peaks 46 of the main index signal feed a line 104 to the frequency mixing circuit 92.

are however opposite in the direction away from each other- The frequency mixing circuit 92 provides when receiving

via comparable peaks 32, which are caused by the receipt of input signals via lines 91 and

constant cathode ray current of FIG. 2 generates advertising 104 an output signal having the 0.5 times value of the

the, relocated. Group of three frequency via line 106 to the fre-

The largest peaks 52 of the modulation of the cathode quenzverdopplungskreis 84. The signal on the Ausdenstrahlstromes for generating the color rendering 100 output line of the phase network 86 is a blue (F i g. 5 a, 5 b) occur fed 108 in accordance with io mixing circuit which with an Andean blue phosphor segments 24 on. The greatest conclusion 110 is provided, over which color reference signals index signal peaks 54 are symmetrical from one another can be recorded. The color reference signal shifted with respect to the index signal peak 32, which may be that usually transmitted at 3.58 MHz by a constant cathode ray current, as in Signal.

F i g. 2 is generated. Several smallest peaks 15 The output signal of the mixer 108 is generated via 56 which, with the signal peaks 32, connects a line 112 to a second mixer 114. 2 match. The symmetrical route, which is suitable for receiving a tone signal at the location of the larger peaks 54 and the smaller ones at its input 116 . The amplitude peaks 56 produce a signal which contains a fundamental component 20, indicated by the color signal being modulated to represent the saturation dotted line 58, of the value of the color to be reproduced. This basic component has a frequency rend the phase of the signal is changed with respect to and phase which is identical to that of the output on the phase of the transmitted color carrier in order to reflect the index signal, which is determined by the constant cathode hue of the color to be reproduced F i g. 2 is generated. The signal is fed to the output line 118 of the fre-

By a in F i g. The system shown in FIG. 8 can be fed to the sequential mixer circuit 114 and has one

unambiguous, phase-determining index signal and frequency, which correspond to the frequency of three groups

the ambiguous index signal speaks for the generation of a, as well as an amplitude that corresponds to the saturation of the

continuous, unambiguous index signal with the color value to be reproduced, and a

Frequency of triples can be used. Phasing or phase modulation that matches the tone of the

A photoelectric cell 78 is outside of the 30 corresponding color to be reproduced.
Cathode ray tube 12 arranged; she is going through. The signal on the line 118 is excited to an adder light which is added by the index elements 30 ' 120 , which is suitable to generate a Y or and 60 as soon as these are struck by the cathode luminance signal via an input terminal 122 beam. The from the photoelectric and a limiter 124 to record. Signals generated by limiting cell 78 are prevented via a zer 124 from feeding the luminance signal to an amplifier 82 under gate 80 . The minimum value drops. This can be done more easily in a more powerful way 82 is tuned to a frequency, which way through a diode tube. It is half the frequency of the frequency which is important for such an interruption for a group of three. The length of time from the amplifier 82 which exceeds the storage of the signal in a frequency doubler circuit 84 of a network 40, since otherwise the generation of the work 86 will not occur. The frequency doubler 84 supplies index signals would be interrupted. The output signal with the triple frequency output signal, which is generated by the adder 120 , on an output line 100 is given to the line 126 . The signal on the

The output signals of the photoelectric cell line 126 comprises the signal on line 118 to -78 are also fed to an amplifier 88 , 45 to which a DC voltage value escapes is tuned to a frequency which, corresponding to the luminance signal at the input, is 2Vä times as large is like the triplet frequency. port 122 has been added. The branch output of the amplifier 88 is fed to a limiting circuit 124 which supplies a minimum DC voltage circuit 90 to an automatic amplitude control value which is sufficient to cause an interruption. The output of the limiter 90 is 50 of the cathode ray of the tube 12 for extended one hand over a line 91 with a frequency to prevent time periods. The luminance signal mixing circuit 92 of the network 86, on the other hand, also determines the luminosity or brilliance of the color. The more positive the DC voltage value of the control signal for a multistable flip-flop circuit 96 signal on line 126 , the greater the supply. The limiter 90 holds its output signal 55 current of the cathode ray, which causes a luminous ratio independent of changes in the other color rendering.
Cathode ray current. If the input signals at terminals 110,

The multi-stable flip-flop 96 supplies its 116 and 122 in the manner that is included

Reset state a signal to the gate 80, which conforms to the transmission standards common in the USA today.

ches talk about the passage of signals to the amplifier 60, then the color reference signal of a

82 prevented; when the flip-flop circuit 96 is derived by apparatus that receives a signal wel-

an input signal on a terminal 98 in its ches the normal color synchronous pulses of the Fre-

Setting state is set, then it delivers a signal that contains a frequency of 3.58 MHz and which the reference switch enables the gate 80 to phase through index signals. The color signal is in the times

allow. 65 between the horizontal synchronous pulses with a second frequency doubling circuit 102 of a frequency of 3.58 MHz given together network 86 is through output signals on the with the reproduction of the Y or luminance signal, line 100, which is from the frequency doubling circuit which in a Frequency range below 3.58 MHz

is sufficiently included. By using suitable filters, the luminance or Y signal can easily be separated from the color signal. These can be used for remote transmission and evaluation Signals are modulated onto a suitable carrier signal which lies in a predetermined band.

The output color signal on line 126 can be fed to a second adder circuit 128, which receives at its input 130 a blanking signal that the electron beam during the Return period interrupts. Because the index signals are not derived from the flyback periods and furthermore, since no color reproduction whatsoever is desired on the screen during this fall-back time, interferes adding the blanking signal in no way does the system work properly, but does modulate it the input signal on line 126 so that a desired output signal on line 72 appears.

The signal appearing on line 72 is modulated in such a way that it contains color information the screen 14 of the cathode ray tube 12 transmits the color information which the television system 64 is supplied, matches.

Claims (3)

Patent claims: 1. Color television receiver with a beam index tube and several color signal generating Segments, which are arranged in groups in a predetermined ratio along a line and several index signal generating elements located along the same line in a ratio deviating from the ratio of the groups as well as from the ratio of the segments, as well as a in the limiter arranged in the luminance control circuit of the cathode ray tube, characterized in that that the limiter (124) interrupts the cathode ray when the luminance signal (122) drops below a Prevented predetermined level. 2. Color television receiver according to claim 1, characterized in that the luminance control circuit (70, 72) of the cathode ray tube (12) with color information signals (118) and with Luminance signals (122) is fed via an addition circuit (120) and the limiter (124) is arranged in the feed line for the luminance signals (122). 3. Color television receiver according to claim 2, characterized in that through the limiter (124) maintain a predetermined minimum level of the luminance signal for a period of time which is greater than that required for painting a group (26) of segments Period of time. 1 sheet of drawings