DE1290578B - Circuit arrangement for connecting a PAL color television receiver to a transmission path or to a recording device - Google Patents

Description

The recording of a composite color video signal is known to prepare Difficulties because of the frequency position of the color carrier in the upper range of the Video signal a high recording bandwidth is required and also the Color carrier due to fluctuations in the speed of the recording carrier which must be eliminated by corrective circuits. Similar difficulties arise even with narrow-band, error-prone transmission paths, such as. B. complicated transmission lines or narrowband lines.

To simplify the recording or transmission, it is known Color signals representing three different color components, one line at a time record or transmit. Here z. B. the recorder or only narrow-band video signals are fed to the transmission path, so that no large Recording bandwidth or transmission bandwidth is required and also none Time errors in the signal can occur. Even with distorted transmission links such a signal can be transmitted more securely than a normal composite color video signal.

These color signals to be recorded or transmitted sequentially generally need a color television receiver or a separate color decoder can be removed.

The invention is based on the object of a circuit arrangement to create with the these color signals in the simplest possible way a PAL color television receiver can be taken with the runtime demodulator.

The invention is based on a circuit arrangement for connection a PAL color television receiver with a time of flight signal splitter circuit to a Transmission path or to a recording device with which using line frequencies Switch three different color components representing color signals line by line sequentially transmitted or recorded, and consists in that the in color-subcarrier-frequency color difference signals brought to the same phase in a manner known per se the transit time signal splitting circuit in a matrix in a manner known per se are dematrixed in three color difference signals color subcarrier frequency and that these the line-frequency switches are fed, which the three color signals line by line alternately switch on a common demodulator, its output voltage is fed to the transmission path or the recording device.

The invention has the following advantages: Since the switch lie in the color carrier frequency path, they do not need any DC voltage components to be transmitted and can be structured more simply. Due to the location of the switches in the Color carrier frequency path also has the advantage that by using a A galvanic transformer or a capacitor in the color carrier frequency path Separation between the receiver and the recording device or the transmission path can be made. This is particularly advantageous for all-current devices whose Chassis may not be galvanically connected to one another. Another advantage the invention consists in that only a single demodulator for all color signals is required.

The invention is illustrated below with reference to the drawings using the example a recording device explained in more detail. The F i g. 1 to 3 show three different ones Embodiments.

In FIG. 1, the complex color carrier sequence F, F + of the PAL color television signal is fed to a transit time signal splitting circuit 1 which contains an adder stage 2 and a subtract stage 3. When the color subcarrier is modulated according to the axes (BY) and ± (RY), the color subcarrier-frequency signal FB_y with constant phase is constantly generated at the output of adder 2, and the color subcarrier-frequency signal ± jF (R_y) with a phase opposite which of the signal FB_y is shifted line by line alternately by 90 and 270 °. The signals FB_y and ± jF (R_y) are brought to the same phase and fed to a matrix 6 by means of a phase switch 5 operated by a half-line frequency switching meander 4, which shifts the signals of this path alternately by 90 or 270 ° at line frequencies. In the matrix 6, the amplitude-modulated color carrier frequency signals FB_y, FG_y and FR_y are obtained in three color carrier frequency channels 7, 8, 9 by color carrier frequency matrixing and fed to three inputs of a switch 10 operated at a line frequency. The switch 10 switches the signals FB_y, FG.y and FR_y line by line one after the other to a common demodulator 11. The demodulator 11 can be a synchronous demodulator or a demodulator working with a carrier add-on. The reference carrier necessary for demodulation is generated in an oscillator 13 which is synchronized by color synchronizing signals which are sampled from the color carrier frequency signal with a gate 14 by means of line-frequency pulses 15. For this purpose, the color subcarrier-frequency signals are fed to the inputs of the switch 10, including the color sync signals. The connection line between the color television receiver and the recording device can, for example, be at a point 16 in the path of the color carrier frequency. In this way, there is preferably a transmitter, either in the receiver or in the recording device, which galvanically separates the receiver and the recording device from one another; which is particularly important for all-current devices.

In the embodiment according to FIG. 2 becomes the color carrier frequencies Color signals at the output of switch 10 still have a constantly present luminance signal Y added. The luminance signal Y is a color carrier frequency in a modulator 17 Modulated on carrier f., Which is generated in an oscillator 18. The oscillator 18 is synchronized by color sync signals, which by means of a gate 19 from a color subcarrier-frequency signal can be sampled out. That the color carrier frequency Luminance signal Y modulated onto the carrier becomes the color carrier frequency in an adder stage 20 Color signals supplied, so that a combination of the color carrier frequency level respective color signal with the luminance signal, which is preferably the high video frequencies contains, takes place. The combined color subcarrier frequency signal at the output of the Adding stage 20 is via a transformer 21, output terminals 22 of the receiver, a connection line 23 and input terminals 24 of the recording side to the Demodulator 11 is supplied, the output voltage of which is supplied to the recording device 12 will. Due to the transmitter 21 lying in the path of the color carrier frequency, a galvanic Separation between the color television receiver connected to the primary winding of the transformer 21 and the recording device 12 connected to the secondary winding. The chassis of these two devices do not need to be connected to one another. The amplitude of the carrier f,) fed to the modulator 17 is selected to be so large that that with the demodulator 11 demodulation without an additional carrier addition is possible is.

F i g. 3 shows a circuit example for the embodiment according to FIG. 1, in which a video-frequency luminance signal Y is additionally added to the color signals at the output of the demodulator 11 in an adder 20 . The adder 2 supplies the color carrier-frequency signal Fe-y, which is brought to the phase jFB_y with a 90 ° phase rotating element 25. The subtraction stage 3 supplies the signal ± jFR_y, which is brought to the constant phase jF, z_y with the phase switch 5. The matrixing takes place with two resistors 26, 27, at the connection point of which the color carrier-frequency signal jFG_y is present. Three diodes 28, 29, 30 serve as switches 10, which are controlled in a permeable manner line by line by control pulses 31, 32, 33 each of a line duration. A transit time line 34 in the path of the luminance signal Y is used to compensate for the transit time of the color signals in the color channel.

The transformer used for galvanic isolation can prevent this have an attenuation point for hum interference at the mains frequency. the Matrix 6, the switch 10 and the demodulator 11 can either be in the housing of the Color television receiver or housed in the housing of the recording device be. The connection line between the receiver and the recording device is preferred behind the switch 10, because then only a single connection path is required is. Between the primary winding and the secondary winding of the transformer can be a additional voltage-proof protective insulation can be provided.

Claims (11)

Claims: 1. Circuit arrangement for connecting a PAL color television receiver with a transit time signal splitting circuit to a transmission path or to a recording device, with which three different color components representing color signals are transmitted or recorded line by line using line frequency switches, characterized in that the in color subcarrier frequency color difference signals (FR-y, FB_y) of the transit time signal splitting circuit (1) in a matrix (6) in a known manner into three color difference signals (Fg_y, BG-y, Fe-y) color subcarrier frequency are dematrixed and that these are fed to the line-frequency switches (10, 28, 29, 30) which alternately switch the three color signals line by line to a common demodulator (11) , the output voltage of which is fed to the transmission path or the recording device (12). 2. Circuit arrangement according to claim 1, characterized in that the demodulator (11) is a synchronous modulator (F i g. 3). 3. Circuit arrangement according to claim 1, characterized in that that the demodulator is an amplitude rectifier working with a carrier addition. 4. Circuit arrangement according to claim 1, characterized in that the color subcarrier frequencies Way a transmitter (21) or a capacitor is provided, the transmission path or the recording device (12) and the receiver are galvanically separated from one another (FIG. 2). 5. Circuit arrangement according to claim 4, characterized in that the transformer has a damping point at the mains frequency (50 Hz). 6. Circuit arrangement according to claim 1, characterized in that the connecting line (23) between Receiver and transmission link or recording device (12) in the color carrier frequency Away. 7. Circuit arrangement according to claim 6, characterized in that the connecting line (23) lies between the switches (10) and the input of the demodulator (11) . B. Circuit arrangement according to Claim 1, characterized in that a luminance signal (Y) is continuously added to the color signals after the line-frequency switches (28, 29, 30) in an adding stage (20) (Fig. 3). 9. Circuit arrangement according to claim 8, characterized in that the luminance signal (Y) is modulated onto a color carrier frequency carrier (to) in an amplitude modulator (17) and this carrier is added to the color signals in an adding stage (20) in the color carrier frequency path (F i g. 2). 10. Circuit arrangement according to claim 9, characterized characterized in that the amplitude of the carrier is so large that the combined color carrier frequency Signal can be demodulated without additional carrier addition. 11. Circuit arrangement according to claim 1, characterized in that the color subcarrier-frequency color difference signals (FB_y, F, 9-y, FR-y) fed to the switches (10) including the color sync signal and this color sync signal is the common path behind the switches (10) removed and used to generate a reference carrier for the demodulator (11) is (Fig. 1).