DE1537019C - Color television receiver with automatic color changeover between black and white and color reception - Google Patents

Description

4. Color television receiver according to claim 3, are controlled. In the part labeled 13 characterized in that the one impedance of the receiver becomes that of the chrominance signal Capacitor (14), and the other signal supplied by series source 10 is a local oscilloscope circuit a capacitor (16) with a 30 lator 11 taken reference oscillation added. Resistance (17) is. · ■ 'The part 13 comprises a chrominance intensifier 15 for

the chrominance signal supplied by the source 10, the

'then arrives at the synchronous demodulator 12. The part

. 13 also includes a connection between the

35 color channel and the local oscillator 11, which consists of two impedances. The first impedance is a adjustable capacitor 14 and the second the

The invention relates to a color television receiver series connection of an adjustable capacitor 16

with automatic color change between with a resistor 17. The two impedances

Black and white and color reception to increase the 40 transmit reference vibrations of different phases,

The constant component of the red color signal component in the color signal and by changing the capacitors can thus-

reception. probably the phase as the amplitude of the added

With a compatible receiver both vibration part can be set.
Black and white as well as color reception can be determined by means of a "color source 10 and speaks at a known temperature". Usually, the type of signal received was used to lock the gray scale or the basic hue to the chrominance enhancer when the "cool", ie white, playful white is set. the interception signal is of the black and white type,
This "cool" white is the white of a black w t rc η
white receiver similar and is generally 50 mode of action (t 1 g. 1)
preferred for black and white reception. When receiving colors, however, it has been found in demodulator 12 that a subjectively warmer derivation of the two color differences RY and BY fundamental tone with a stronger admixture of red takes place. The basic color tone of the reproduced image is perceived as more pleasant when receiving colors, depends on the bias on the control panel, especially when reproducing skin-like colors on the picture tube, which are usually set in this way. . ^; that when receiving black and white a "cool"

The purpose of the invention is to create sheep white. If you want to receive a color

function of an automatic change of the color tone, get "warmer" white, then the preload should

This makes the red control grid look like the type of signal received compared to the green one

is fitted. : 60 and increased to the blue control grid.

In a known receiver (USA.-Patent- This is achieved by the fact that via the connection 2 954 326) this is part of the local reference oscillation through a connection from the local color carrier oscillator 11 to the "red" control grid of the picture tube to the color color channel Reached trap circuit, whereby the red control grid is fed to the chrominance signal and then to be at a higher voltage in the demodube during color reception 65 lator 12 is demodulated. With the right choice that comes. As a result of this, however, the bias phase can lead to an increase in the DC component of the supply of the red control grid from that of the RY . When receiving black and white, the blue and the green control grid are separated, and the amplifier 15 is controlled by the color blocking circuit 18.

blocks, and the basic color is then only based on the rest pre-stresses on the control grids the picture display tube.

The fact that there are two adjustable impedances 14 and 16, 17 gives rise to the possibility to adjust not only the phase but also the amplitude of the added reference oscillation.

Fig. 2

F i g. 2 shows exemplary embodiments of the units 12 and 13. The input side of the color blocking circuit 18 is connected to the phase demodulator of the receiver and supplies a bias voltage to the output circuit of the chrominance signal source 10, through which the amplifier 15 'belonging to the color channel switches on or off depending on the type of received signal is turned off. The impedances 14 and 16, 17 are connected to a point F ₄ in the color channel, where the phase position of the color carrier is 180 °, and are on the other hand with points F ₂ and F ₃ at the output of the local oscillator, where the Phase positions are 270 or 90 °. Point V ₂ belongs to a winding of the output transformer from which the voltage reaches the phase demodulator, while point F ₃ belongs to another winding whose voltage is used to control synchronous demodulator 12.

The amplifier 15 'serves to simultaneously amplify the chrominance signal and the green color difference voltage GY, which is fed to point F _{4 of} the input circuit. This point lies via a resistor 26 on the control grid of the amplifier tube 51, the cathode of which is connected to earth via a bias network consisting of a resistor 29 with a shunt capacitor 30. _{The anode is connected to the positive terminal of the bias voltage source F 1} via the primary circuit of a transformer 56, which is tuned by a capacitor 28, and via a resistor 54. The secondary circuit of the transformer is tuned to the chrominance carrier frequency by a capacitor 31, as is the primary circuit, and the amplified chrominance signal passes from the secondary circuit to the synchronous demodulator 12. The amplifier also has a low-frequency output circuit, which consists of a capacitor 27 together with the resistor 54, and from which the amplified color difference voltage GY is taken out.

The demodulator 12 comprises two triodes 52, 53, the cathodes of which are connected to the collector-emitter circuit of a transistor 55 with a grounded emitter are periodically placed on ground potential and in the intermediate intervals are isolated from it. The switching of the transistor 55 between permeable and impermeable The state is found by a device taken from the local oscillator 11 and arriving at the base Control voltage instead, which reaches the base via capacitors 45 and 47. This lies over the series connection a resistor 49 with one of a resistor 50 shunted to a capacitor 48 existing bias circuit to earth. Between the common point of the capacitors 45, 47 and the bias circuit 48, 50 is a resistor 46.

Since the tubes 52, 53 become permeable at the same time, the chrominance signal has to go to their control grids get with different phase. For this purpose lies between the input terminal of the demodulator 12 and the control grid of the tube 52 a capacitor 32, while the control grid has a Resistance 33 is connected to earth. The control grid of the tube 53 is connected to ground and via a resistor 44 via the series connection of a resistor 43 with a coil 42 at the input terminal of the Circuit.

As a result, the tubes demodulate the chrominance signal at different phase angles. The demodulated voltages are taken from the anode circuits. The anode circuit of tube 52 includes a resistor 34 between the bias _{source F 1} and the output terminal and a coil 35 in series with a resistor 36 between the output terminal and the anode. The anode circuit of tube 53 similarly includes resistor 39, coil 40 and resistor 41. Demodulator 12 operates at a high voltage level and has excellent DC stability, but when used together with the one shown in FIG. 2 is used, a disadvantage which is eliminated by the present invention.

In the demodulator 12, a strong reference oscillation component is coupled over from the cathodes to the grids of the tubes 52 and 53, which is demodulated in the same way as the color signal and thereby influences the direct component of the derived color differences. This need not be disadvantageous per se, since the desired basic color can be achieved by adjusting the grid bias of the picture tube, taking into account the additional biases produced by the coupling. When receiving colors, however, the color blocking circuit 18 makes the amplifier 15 'permeable and changes the resistance of the input circuits of the tubes 52 and 53. This also changes the cross-coupled reference oscillation component, and the constant components of the color differences experience corresponding changes that affect the basic color in an undesirable manner.
This disadvantage is also eliminated by the present invention. By appropriately setting the capacitors 14 and 16, a reference oscillation component with the desired phase and amplitude can be added for color reception. Should it be desired to keep the same basic hue in both black and white and color reception, the added vibration component can be chosen to compensate for the effect of the change in the input resistances of tubes 52 and 53.

1 sheet of drawings

Claims (3)

1 2 advantages associated with a common supply of all three control p ... grids are lost. Claims: The object of the invention is> to eliminate this disadvantage. 1. Color television receiver with automatic 5 According to the invention, this is achieved by a connection Hue switching between black and white and from the output of the local color subcarrier oscillator and . Color reception to increase the direct component of the red "color signal component located in front of the synchronous demodulator" when receiving color, ge point of the color channel shown, whereby, when characterized by at least one Im- color reception the color signal to be demodulated pedanz (14; 16, 17), the connection between seeing a portion of the local oscillator vibration is added to the output (F ₂ ; F ₃ ) of the local color. carrier oscillator (11) and one in front of the syn- Fig. 1 is the block diagram of an embodiment chrondemodulator (12) lying point (F ₄ ) of the form; Represents color channel, whereby when color reception F i g. 2 shows a modified embodiment, the color signal to be demodulated is a component 15 in FIG. 1 is with 10 the chrominance signal source of the the local oscillator oscillation added called the receiver. The color signal includes the will. Sidebands of the modulated color carrier. It can 2. Color television receiver according to claim 1, further containing the synchro-color symbol. With characterized in that the impedance (14; 11 is the local color carrier oscillator, 16, .17) to change the phase or the ampli- ao which is synchronized by the color sync symbol tude of the vibration transmitted through it. The output voltage of the oscillator 11 controls is adjustable. a synchronous modulator 12, which in a known manner 3. Color television receiver according to claim 2, from the modulated color carrier a pair of color, characterized in that the connection voltages, e.g. B. RY and BY . The two adjustable impedances (14; 16, 17) sub-modulator can be comprised of several reference oscillations of different structures. of the local oscillator with different phases