DE2028631B2 - Television receiver - Google Patents

Description

40

The invention relates to a television receiver, in particular one for several operating modes, with which both wirelessly transmitted RF television signals and video signals from a tape recorder, a television camera or other suitable video source.

Television receivers are widely used for entertainment, education, educational, sub v> richts-, industrial and other purposes. In many places besides the well-known television broadcasting stations there are other stations whose main function is to transmit programs and information of an educational nature. w

A receiver used in this particular environment should, in order to be universally usable, desirably be able to receive these broadcast programs as well as those pre-recorded on tape. Furthermore, some teaching systems are equipped with camera devices with which a teaching presentation or another relevant event can be recorded locally and transmitted to several other locations via a cable system. Accordingly, the signals that a <■■ '< such a receiver must be able to process are of fundamentally very different types.

The main differences are as follows:

In the case of HF transmission, the video information is modulated onto a carrier, which is received and amplified into a IF signal must be converted, gain controlled and then demodulated. Tape devices and cameras on the other hand deliver a normal standardized video signal (e.g. NTSC signal) directly, which is not a carrier is modulated. During HF transmission, various interferences can affect the signal before demodulation of the useful video signal. Such influences are frequency and phase dependent, so that at the design of the receiver must be taken to ensure that a to ensure optimal playback.

Such disturbances or distortions have an even greater effect on color transmissions, so that in a color television receiver, certain precautions must also be taken. For this include an optimal training of the IF and HF amplifiers as well as certain equalization and Delay measures in the chrominance and luminance channels of the receiver.

When a television signal is not sent wirelessly and is not modulated onto a carrier, but in Form of the actual NTSC signal or a video signal that corresponds to the signal that is in the Receiver normally obtained through the demodulation process is available, so may Signal can be fed directly into the first video amplifier stage or into the video amplifier chain. if however, the receiver should also be able to process a transmitted RF signal, so the input of a such signal can only be successfully accomplished if the differences between the direct Video information signal and the video signal obtained from the transmitted RF signal taken into account will. A receiver that is compatible in the sense that it can carry both a transmitted RF signal as well as video signals from other sources such as tape recording must process and resolve these differences.

It is expected that in the very near future the general public will see tape devices, camera equipment as well Pre-recorded tapes for normal home receivers with both color and black and white reception for Will be available. These devices and products will enable consumers to For example, to make your own color tape recordings and play them on your television receiver or purchase pre-recorded tapes for this purpose. Furthermore, the consumer will if such Funds are available, in certain cases, a desire to broadcast a television broadcast Tape the program he receives on his home receiver for future use. In order to realize a universal television receiver that can be used for such purposes, one must, as will be shown, certain considerations must be taken into account in order to be a recipient receives, which is relatively cheap and still guarantees optimal playback.

The invention is based on the object of such a multipurpose television receiver that this Needs is enough to create. The television receiver provided according to the invention to achieve this object includes an automatic gain control (AGC) circuit of a known type as well as a selectively operable arrangement, which the EmDfäneer

switches to a first operating mode in which it reproduces a television picture upon receipt of a high-frequency carrier modulated with a television signal composite. The selectively operable arrangement can also be switched to a second operating mode in which the receiver responds directly to an external video signal that is not assigned to a high-frequency carrier. In a third operating mode, the receiver delivers a video signal in the form of a composite television signal for external use. The automatic gain control circuit is set up so that, when the selectively operable arrangement is switched to the second and / or third operating mode, it can act on the external video signal and on the internally supplied video signal. \ ^r >

The drawings show

F i g. 1 shows the block diagram of a television receiver with one of the receiver's AGC circuit regulated amplifier according to an embodiment of the invention, 2ü

F i g. Figure 2 is a block diagram of a color television receiver receiving both external video signals and a Can process RF carriers on modulated video signals,

F i g. 3 shows the circuit diagram, partly in block form, of a color television receiver for the Reception and recording of transmitted RF signals as well as for direct processing from outside Video signals and

F i g. 4 the circuit diagram of a horizontal oscillator Jo and phase detector arrangement which can be used in a universal receiver according to the invention.

In setting up a television receiver to receive video information that is not modulated onto a carrier, it is desirable to input the video signal 1 *> directly into the receiver's video amplifier. The input signal should preferably be approximately equal in its size or its level to the signal level that prevails at the input point when the receiver processes a transmitted RF signal, ίο For example, in the case of a receiver with vacuum tubes, it would be desirable to have the signal on the grid or on the cathode of the first amplifier stage, ie the video amplifier stage immediately following the video demodulator. The automatic gain control circuit (AGC circuit) of the receiver, which is usually controlled by this amplifier stage, then receives a signal that corresponds or is similar to the signal that is fed to it during normal reception operation. In normal reception mode, ie when a transmitted RF signal is received, the AVR circuit regulates the gain of the tuner and the IF amplifier so that, regardless of fluctuations in the antenna signal strength, the instantaneous level of the horizontal ^{synchronization pulse r} > i peak is held at a predetermined value. Automatic gain control is a common function that a typical television receiver can perform to provide optimal reception in all channels and in all signal propagation conditions. If the receiver is not processing an RF signal, the AGC circuit can still be used in conjunction with a other video source such as tape, television camera, etc. can be used.

In Fig. 1, transmitted RF television signals which '■' · are received with the antenna 10, the input of the receiving part 11 of the television receiver with tuner, IF amplifier and video demodulator supplied. The RF signal is amplified in the tuner into an IF signal Lower frequency converted and demodulated, so that at the output of the video demodulator a demodulated Signal is ready. These functions are well known and in most coloring and Realized with black and white receivers.

The output of the video demodulator is in a conventional manner a video amplifier chain 12 and from fed to the picture tube 14 there. The input side of the video amplifier 12 is also connected to the picture tube 14 coupled deflector 15 coupled to the synchronizing, deflecting and high voltage generator circuits. The deflection part 15 supplies the deflection signals and operating voltages for generating a raster the screen of the picture tube 14.

In most receivers a keyed AGC circuit 16 is provided, which the gain of the tuner and the IF amplifier so that, regardless of the received signal strength, the current Synchronizing signal level is held at a predetermined value. The keyed AVR circuit supplies the control voltage that corresponds to the size of the video signal at a specific point in the video amplifier chain is proportional and fed to the RF amplifier or tuner as well as the IF amplifier, to increase or decrease the received signal strength at the antenna To regulate the amplifier down or up. In this way, the one leading the synchronization information becomes Part of the signal amplitude in the receiver is relatively constant and independent of the channel on which the Receiver is tuned, or of the different received signal strengths normally to be expected held on the antenna 10.

The AVR function in the receiver is therefore relatively important with regard to optimal reproduction over a wide range of changing signal amplitudes.

In Fig. 5 is also a switch 20 with three contacts to a tape device (tape recorder) 21, one Television camera 22 and a further video source 23 are coupled. The moving contact or arm of the Switch 20 is connected to a potentiometer 24, the wiper of which has alternating current via a capacitor 25 is coupled to the input of a DC-coupled video amplifier 26, which is connected to its output is connected to the contact arm of a mode selector switch 27. When set to One fixed contact or pole of switch 27 is a connection to the input of video amplifier 12 established, while this connection is interrupted when the second pole is set. The entrance of the DC-coupled video amplifier 26 is also via a resistor 29 to the output of a second DC amplifier 30, referred to as "polarity amplifier", coupled. The entrance of the Amplifier 30 is connected to the output of the operating mode selector switch 27 via a further section 31 keyed AVR circuit 16 switched on. By means of a further contact 32 of the operating mode selector switch 27, the receiving part 11 can be switched off from the operating voltage β +, so that the tuner, the IF amplifier and the video demodulator can be switched off. In Fig. 1, all are at the top mentioned contacts of the operation selector switch switched to the video monitor position. The switch 20 is on the output of the tape recorder 21 is switched, whose signal thus appears on the potentiometer 24. With the

Potentiometer 24 is the input signal level regulated or adjusted to the device to the different Adjust expected signal levels from tape devices, cameras, and other video sources. With the in F i g. 1 shown conditions, d. that is, with the mode switch in the video monitor mode, the mode of operation is of the recipient as follows.

The tuner, the IF amplifier and the video demodulator (receiving part 11) are switched off because B + has been switched off, so that no signals due to HF transmission can reach the video amplifier. The tape recorder 21 (for example) has its output connected to the input of the DC-coupled video amplifier 26. The video amplifier 26 receives the signals played by the tape recorder, amplifies them to a suitable level and switches them via the switch 27 to a stage of the video amplifier 12 close to the input. The video amplifier 26 is preferably coupled to that stage or pre-stage of the video amplifier 12 which does the synchronizing and feeds AVR circuits. Thus, after entering the signal from the tape recorder, the receiver works in the usual way. However, the signal from a tape, television camera, or other video source may vary in amplitude due to the specifics of the source. A corresponding setting of the potentiometer 24 is therefore just as important for correct reproduction as in the case of HF transmission.

The keyed AGC circuit 16 is connected to the DC polarity amplifier via the switch section 31 30 is turned on, the output via the resistor 29 to the input of the video amplifier 26 is coupled. The signal voltage from the AGC circuit 16 is used after amplification by the Polarity amplifier 30 to bias the input of the DC coupled video amplifier 26 over the resistor 29. Due to the polarity of the signal supplied, there is negative feedback for the amplifier 26, while the DC amplifier 30 provides sufficient gain to the Morning care! the horizontal sync pulse peaks at the same place in the video amplifier at the same predetermined value.

As in Fig. 1 shown, the AVR circuit is thus « 16 Part of the automatic bias circuit for monitor operation of the receiver in conjunction with other video sources. The advantages of this special system are that the operating points of the Amplifier 12 are the same as in normal operation when receiving transmitted RF signals. As a result there is only a slight shift in brightness when switching between the different operating modes external sources and RF reception. In addition, due to the fact that the synchronizing signal peaks kept at a fixed level by the AVR is an effective black control (Reintroduction of the direct current component) of the signal coupled to the picture tube, so that the The viewer is offered an optimally bright picture.

So it becomes the receiver's own AVR circuit 16, which is normally on the tuner and IF amplifier acts, exploited in an advantageous manner when the receiver is used as a monitor device Playback of other video signals is working. As a result, all the advantages of the AVR are retained are required when working with external sources such as tape devices, cameras, etc. while at the same time it is ensured that what it is based on is brought out of the television receiver Can achieve construction without significant changes to the internal parameters of the Must be made to the recipient. This enables the recipient to do essentially so too work as it should work in RF transmissions by the in Fig. 1 mode selector switch shown is only switched to the position shown in dashed lines.

The use of the AVR circuit described above can be used with the same advantage in black and white as Color receivers can be realized.

F i g. Fig. 2 shows the block diagram of a color television receiver, which focuses on both the reception of broadcast RF programs as well as the playback and control of video signals sent by others Sources such as a television camera 22, tape recorder 21, or other suitable video source 23 originate, can be adjusted.

The television receiver according to FIG. 2 works with the same AVR scheme as the receiver according to FIG. 1, so that the same circuit parts that fulfill corresponding functions have the same reference numerals are designated. The main difference between the color receiver and the black and white receiver is the Chroma channel, one of the essential components of which is a chrominance intensifier 40, which consists of one or multiple stages of selective bandpass amplifiers with a given gain and within of the color carrier signal range is centered frequency response. A burst signal separator 41 is picked up by a pulse picked up by the horizontal synchronizing circuit of the deflector 15 periodically keyed into the conductive state, so that it has an amplified version of the at its output Color transmissions transmitted color sync signal vibration train delivers. The output of the burst signal separator 41 is coupled to a chrominance or reference oscillator 42 which is connected to the Color synchronizing signal phase-synchronized output signal! with color carrier frequency for demodulating the Provides color carrier sideband signals. The output side of the reference oscillator 22 is therefore connected to an input of the Color demodulator 43 coupled with another input to the output of the chrominance amplifier 40 is coupled. The output of the demodulator 43 is connected to corresponding electrodes of the color picture tube 45, which can be a three-beam shadow mask tube, is coupled.

An AFR and color barrier circuit 46 is coupled on the input side to the reference oscillator 42 and is used to the amplitude of the color sync signal at the output of the chrominance amplifier 40 regardless of to keep fluctuating input signal strengths at the antenna relatively constant. This so-called automatic Color regulation (AFR) complements the action of the AVR for the higher frequency chrominance components, the selective attenuation due to the properties of the propagation path and other changes or attenuation. In addition, the AFR and color blocking circuit 46 serves to increase the chrominance 40 to be switched off or blocked for black and white transmission in order to prevent interference or External signals affect playback. The circuit parts described above are general known and present in most conventional color receivers,

In the luminance channel there is, as is usual in a color receiver, a delay line 47 to compensate for the longer transit time or delay which the chrominance signals experience during treatment in the narrowband chrominance amplifier compared to the luminance signals amplified in the broadband luminance amplifier (video amplifier 12). In the delay line 47, the luminance signals are delayed so that they arrive at the cathodes of the picture tube at the same time as the arrival of the associated chrominance signals at the grids of the picture tube. When the receiver is operating in video monitor mode, as in connection with FIG. 1 mentioned, for example, the operating voltage B + is switched off by means of the switch 32 from the IF amplifier. The switch 32 may be a suitable disk or contact arrangement on the mode selector switch 27. The receiver can now process a video signal fed directly into the video amplifier.

If the IF amplifier effect fails, i. H. however, when the IF amplifier is switched off An interesting phenomenon in that the delay of the delay line 47 is now too long and consequently the chrominance signals with this delay, at that prevailing in a conventional receiver Conditions before the arrival of the luminance signals at the cathodes on the grids of the picture tube arrive. It must therefore, so that a conventional receiver both signals that wirelessly by means of a Carrier as well as video signals coming directly from an appropriate source such as tape or a camera can process the delay of the luminance delay line 47 can be shortened or reduced when switching to monitor mode. Hence, with the Mode selector switch connected to a contact 48 which forms part or section of the delay line 47 shorts when the receiver is used as a monitor device for reproducing color video signals from a tape or works from other sources.

F i g. 3 shows, partly in block form, the circuit diagram of a typical commercial color television receiver, which is modified to receive both wirelessly transmitted RF signals and video signals from other sources can handle.

The antenna 49 is connected to the input of the HF tuner 50 coupled, the output signal of which is fed to the IF amplifier 51. The IF amplifier 51 is coupled on the output side to the input of the video demodulator 52 and to the audio part 54 of the receiver. The video demodulator 52 is coupled in the usual way directly to the input of the video amplifier, which in this case has an input stage 56 with a pentode. The anode of the pentode is attached to the Lattice of an amplifier triode 57 coupled, which has an anode and a cathode load resistor for the Control of the synchronization and AVR circuits or the luminance channel has.

The anode of the amplifier triode 57 is connected to the input of the synchronizing signal separator 61 as well as via a Resistor 62 coupled to the input electrode of a keyed AVR pentode 60. The pentode will be 60 sensed by positive pulses which are passed between the anode of the pentode 60 and the deflection circuit 64 coupled capacitor 63 are supplied. The keyed pentode 60 provides one to its anode Control voltage that corresponds to the amplitude of the synchronization signal peaks of the signal fed to the grating is proportional. The anode load contains suitable /? C filter elements for filtering the control voltage their feed to the RF and IF amplifiers. The deflection circuit 64 includes the vertical and horizontal deflection stages with flyback transformer and the various high-voltage levels, as they are in one usual recipients are usually present.

The deflection circuit 64 supplies the deflection yoke 66 of the picture tube 67 via two outputs A "and Y, the one

ίο can be three-beam shadow mask tube, with the necessary horizontal and vertical deflection vibrations. The control signals for the deflection circuit are supplied by the horizontal oscillator 68 and the vertical oscillator 69, which are synchronized by the synchronizing signal separator 61. As is customary in such a receiver, the chrominance treatment circuit 70 with the chrominance bandpass amplifiers, the color sync signal separator, the reference oscillator, the AFR circuit and the color blocker is controlled by the input stage 56 of the video amplifier, which is connected to its anode via a capacitor 71 the chrominance treatment circuit 70 is coupled. The outputs of the chrominance treatment circuit 70 are coupled to the color demodulator 72, which supplies color difference signals for the feed line to the picture tube 67 via the color driver stages 73. In normal reception mode, the cathode output of the video amplifier triode 57 is coupled to the input of an additional luminance delay line 76 via a switch contact 74, a delay line 120 and then a switch contact 75. The output side of the delay line 76 is coupled to the input of a video amplifier 77 which, via a suitable control network 78, controls the cathodes of the picture tube 67 with the relatively broadband luminance signals. The delay lines 120 and 76 serve to ensure that the broadband amplified luminance signals arrive at the cathodes of the picture tube 67 approximately simultaneously with the arrival of the chrominance signals at the picture tube grids. The receiver, as described so far, is conventional with the exception of the switch contacts 74 and 75 and the split or split delay line 120, 76.

The additional circuit that is used in the receiver for reception will now be described in detail provided by external video signals, for example from a tape recorder or a camera is.

The mentioned switch contacts 74 and 75 are contacts on the same switch, the other contacts 80, 81, 82, 83 and 84 controls. Each of these switch contacts. is designed as a single pole changeover switch, although other suitable switch arrangements are also used can be. In Fig. 3 there is shown a switch operating diagram indicating that when the switch contacts 74, 75 and 80 to 84 are switched to the position shown in dashed lines or upwards, the Receiver processes an RF transmission in the usual way. If the switch contacts on the The positions shown in the drawing are switched, the receiver responds to an external video signal sent by from one of the above sources.

In the case of the in FIG. 3 illustrated switch position, corresponding to the use of the receiver as Video monitor device, a source of external video signals is coupled to port 86, which in turn is connected to one end of a potentiometer 87 is connected

is. The potentiometer 87 serves as an input signal level control which enables the user to adjust the strength of the signal fed to the receiver. The wiper of the potentiometer 87 is coupled in terms of alternating current via a capacitor 88 to the base of an amplifier transistor 89. The amplifier transistor 89, which is connected as an emitter follower, has its collector connected to an operating voltage source + V «via a current limiting resistor 90. connected. The collector is bridged by a capacitor 91 for alternating current signals. A base bias network for transistor 89 comprising resistors 92 and 93 is connected between + V _1x and the base of the transistor. The emitter of transistor 89 is connected to reference potential (ground) via a load resistor 94 and is coupled via a coil 95 to the base of an amplifier _{transistor 96, which is designed as an emitter circuit and a collector load consisting of the + K re} and the collector of this transistor coupled Series connection of a resistor 99 and an equalization coil 100 .

The coil 95 lying between the emitter of the transistor 89 and the base of the transistor 96 is in series resonance with a capacitor 101 which is connected in series with a Q damping resistor 102 between the base of the transistor 96 and ground. Coil 95, capacitor 101, and resistor 102 form a low Q resonant circuit that functions as an IF amplifier simulator for the color carrier signal components. The collector of transistor 96 is coupled to the base of an amplifier transistor 105 , the emitter of which is connected to + V _1x via the series connection of resistors 106 and 107 . A bridging or bypass capacitor 108 is coupled between the connection point of the resistors 106 and 107 on the one hand and ground on the other hand. The collector of transistor 105 is connected to ground via a resistor 109 and to the switching arm of switch 83, which, as shown, is connected to receive external video signals. The switch 83 couples the collector of the transistor 105 to the cathode of the first video amplifier stage 56. This coupling enables the direct coupling of the video signal amplified by the above-mentioned stages to the cathode of the first video amplifier stage 56 the switch contact 80, the operating voltage B + from the IF amplifier 51 is switched off. This switches off the receiving part of the receiver so that no HF signals can be received and processed in video monitor mode. Amplifier pentode 56 amplifies the signal coupled to its cathode so that it provides amplified video signals to its assemblies as they would normally appear there upon RF reception. Furthermore, the coil 95 in conjunction with the capacitor 101 deliberately affects the video signal from the external source as it would if it had been obtained by demodulating an IF signal,

To this end, the low Q series network is sized so that its resonance peak is about 3.08 MHz or slightly less. This enables the ink sub-sideband frequencies can be amplified on the sloping part of the bandpass curve. When transferring RF signals would have the chrominance or color carrier sideband frequencies through the IF amplifier on the same point, relatively same slope of the bandpass curve of the IF amplifier is amplified.

The purpose of this low @ series resonant circuit, therefore, is to provide an optimal video signal (e.g. NTSC signal), in which the amplitudes of the chrominance and luminance components are proportionate are flat and have no distortion in the course of propagation or due to the IF and HF amplification have learned to intentionally distort.

ίο Many stages in a receiver are designed to adequately process the transmitted RF signals. Examples of this are the bandpass characteristics of the RF and IF stages, etc. Taking these facts into account, the optimal video signal must be pre-distorted before it is coupled into the first video amplifier stage of the receiver so that it can be processed by the receiver in the usual way. The amplified signal at the anode of the pentode 56 is now coupled in the usual way via the capacitor 71 to the chrominance treatment circuit 70 and from there to the remaining part of the chrominance circuit, so that the picture tube 67 is supplied with the correct color control signals. As can be seen, as far as the chrominance treatment channel is concerned, there is no difference between these external signals and signals it would receive upon RF reception. The chrominance equalization networks usually present in such a receiver still equalize the chrominance signal before it is input into the demodulator in order to compensate for the "rolling" of the chrominance components due to the IF frequency response, etc. the influence of coil 95 and capacitor 101 has been intentionally pre-distorted as mentioned above.

The amplified video signal at the anode of the pentode 56 is transmitted to the grid of the amplifier triode 57 coupled. The amplified signal appearing at the anode of the triode 57 is of course still over the resistor 62 coupled to the keyed AVR pentode 60 and the synchronization signal separator 61 forwarded. In this way, the horizontal and vertical oscillators 68 and 69, respectively, and the deflection stages are obtained 64 similar or similar signals as would be received with normal reception (HF transmission), so that they have the necessary voltages and deflection currents for the raster-shaped beam deflection deliver. The AGC circuit on the other hand, that normally

so it is coupled to the tuner and the IF amplifier, works, but does not regulate these stages because they are due to the disconnection of the operating voltage B + from

z. B. the IF amplifier 51 are switched off.

However, the anode of the pentode 60 is coupled via resistors 108, 109 and 110 to the cathode of a diode 111 , the anode of which is coupled to the base of an amplifier transistor 112 , the emitter of which is grounded and its collector to the connection point of the Resistors 92 and 93 in the base bias network of transistor 89 is connected. The cathode of the diode 111 and the base of the transistor 112 are also connected via a resistor 114 to the switch contact 84, the voltage + V _y through the video monitor operation

Resistor 116 sends through which transistor 112 and diode 111 are forward biased. In this way, when the diode 111 is forward-biased, the pentode 60 at the resistor 110 in the anode circuit

The AGC voltage fluctuations that appear modulates or changes the bias voltage of the transistor 112. The transistor 112 changes the current of the transistor 89 by controlling its current conduction Base current. Consequently, the changes in the collector current of the transistor 89 become the operating voltage Changed at the base of transistor 96. Transistor 112 also reverts to its base coupled voltage fluctuations in their polarity U.11, so that it is ensured that the automatic Pre-tensioning action in the correct phase according to the number of pre-amplification of the outer The stages used in the signal.

The way it works is as follows. When the DC level of the signal at the base of transistor 89 becomes too positive, the DC level of the on the cathode of the first video amplifier stage 56 also becomes coupled signal too positive, so that consequently the DC level of the amplified signal at the anode the pentode 56 becomes too positive. The AGC key pentode 60 therefore receives a video signal at its grating such a DC level that it cannot conduct, d. H. is locked. Conducts in this operating mode hence transistor 112 stronger. Through the reinforced Conduction of transistor 112, the DC voltage at the base of transistor 89 is suppressed. In this way, the DC level of the signal applied to transistor 96 lowers as well the DC level of the signal appearing at the collector of transistor 105, which is the cathode of the Pentode 56 is supplied. This lowers the DC level at the anode of the pentode 56. on in this way, consequently, the level of the video signal at the anode of the pentode 56 becomes approximately the same Value held as with normal RF reception so that the AGC circuit can conduct and the preamble and Operating points of the video amplifier are kept relatively constant and under the influence of the AVR.

The amplifier triode 57 controls its cathode and the switches 74 and 75, which have two of their contacts are connected together, the luminance delay line 76. The other contacts of the switches 74 and 75 are through with the switch in RF receive mode (i.e., switch arm up) coupled to delay line section 120. The delay line 120 is therefore in series with the Delay line 76, as mentioned above, so that there is a longer delay for the luminance channel when receiving RF than when receiving the external video signal. With HF reception with de * worked with the same delay as when receiving external video signals, when receiving the external video signals the luminance signals at the cathodes of the picture tube after the arrival of the Chroma signals arrive at the grids. It is believed that the need for such Delay adjustment results from the fact that the IF amplifier and the HF amplifier are switched off and consequently do not delay the chrominance components of the signal mixture by a different amount can as the luminance components. The chrominance components therefore appear in normal RF reception at the anode of the pentode 56 with an additional delay from the luminance components due to the properties of the receiving part before input into the chrominance treatment circuit 70. This additional delay does not occur when receiving video signals from other sources necessary on.

The switch 81 does one upon receipt of signals from a tape recorder or other external source another useful task by having the accompanying sound portion of the external signal on a separate tape spui be recorded or come from a suitable sound amplifier circuit, from an output side The preamplifier 121 connected to this switch is coupled to the sound section 54 of the television receiver This coupling can be done via the volume and tone controls of the reception. The so coupled The audio signal bypasses the audio demodulators, as the external audio signal belonging to the external video signal appears in its original form. Aul in this way can see the video signal on the screen the picture tube, while at the same time the accompanying sound over the loudspeaker of the receiver is reproduced so that the viewer is presented with a normal performance.

The switch 82 is connected to ground with its switching arm and its two contacts or poles are connected to the Horizontal oscillator 68 turned on. In series with that contact of the switch 82 on which at HF reception is switched, there is a resistor 123 The other contact, on which uttered upon reception Video signals is switched is connected directly to the oscillator 68.

The switch 82 fulfills the following tasks. The horizontal oscillator is used in normal reception mode 68 synchronized by the synchronizing pulses from the synchronizing signal separating stage 61. Eir The phase detector provides one of the phase differences between the synchronizing pulses and the oscillator oscillation corresponding control voltage for the frequency control of the horizontal oscillator 68, damii this is synchronized in the correct phase. The output signal of the phase detector is pre-filtered to prevent interference and other components from incorrectly influencing the control voltage and bring the oscillator 68 out of step in terms of frequency. In normal reception mode, courage the control voltage is subjected to a narrow-band filtering before it is fed to the oscillator because worse or unfavorable noise or signal-to-noise ratios are to be expected with HF reception.

When receiving signals from other external sources, especially from a tape recorder, bring on the other hand, such a filtering of the control voltage from the feed line to the oscillator poses problems. Be a typical tape recorder for recording and playback of video signals including such Mixed signals, as they are required for color transmission, are scanned using helical lines worked, with the recording and playback of the video information with the help of several, accustomed borrowed two magnetic heads.

Typically for this purpose two magnetic heads arranged at a distance of 180 ° on a head wheel are used, one of which always runs off the banc when the other runs onto the tape. Away mechanical tolerances of the tape device and the alignment of the heads, etc., the width de; Horizontal synchronizing pulse fluctuates in that ei can happen that when playing the on da; Tape running head starts to play the horizontal synchronization pulse in a different phase than de: head straight off the tape. The filter provided for the phase detector during RF reception

network is dimensioned with regard to the expected interference level of the incoming video signal. The filter network therefore undesirably slows down the speed of response to the phase detector output signal than is necessary to take account of the phase disturbances in a played signal. Consequently, the filtering behind the phase detector must be reduced. For this purpose, the switch 82 is provided, which has the effect that the amount of effective filtering is reduced in the video monitor mode, so that the phase detector for the horizontal oscillator 68 can respond to any phase changes in the horizontal synchronization pulse during tape playback. Due to the enlargement of the filter pass band, the receiver can follow such fluctuations more quickly during monitor operation and consequently maintain the phase synchronization of the horizontal oscillator 68 even in the event of disturbances accompanying the horizontal synchronization pulses.

The above description shows how the recipient should be modified as a whole, in order for the various signal sources each with optimal playback regardless of the type of Obtaining the video information to be ready to receive.

Another function that such a universal receiver has to fulfill is the possibility of tape recording of received television broadcasts in HF mode. As already mentioned, for the purpose of receiving RF transmissions, switches 74, 75 and 80, 84 are switched to the position shown in dashed lines (contact arms up).

As in Fig. As shown in FIG. 3, the cathode of triode 57 is coupled to the input electrode or base of an amplifier transistor 125. There is a selective network between the cathode of the triode 57 and ground. A resistor 126 is connected between the cathode of the triode 57 and the base of the transistor 125. Between the base of transistor 125 and ground is the series connection of a resistor 127 and a coil 128 as a voltage divider for the bias voltage of transistor 125. Parallel to resistor 127 and a capacitor 132 is an AC series element 130, 124 for HF compensation. Parallel to coil 128 is a capacitor 131 which, together with this coil, is in resonance at the higher-frequency end of the composite signal spectrum or in the vicinity of the frequency range of the color carrier components.

This resonance network mainly forms an equalization network for equalizing or increasing the color carrier components of the signal mixture at the cathode of the triode 57, so that the attenuation or attenuation of these components is compensated for in the IF and RF amplifiers. In this way, the amplitude distribution of the signal fed to the base of transistor 125 essentially corresponds to the usual standardized video signal (e.g. NTSC signal). The designed in common-emitter transistor 125 has a collector load resistor 135 and a ω emitter degeneration resistor 136. Between the collector of the transistor 125 and the base of transistor 139 is coupled to a delay line 138, which is a differential delay between the luminance and chrominance components "of about 0.2 Introduces microsecond.

As you can recall, a different delay in the luminance components is required in video monitor operation than in RF reception, since in this case the HF and IF amplifiers are bypassed, which also results in a differential delay between the chrominance and luminance components of approximately 0.2 microseconds compared to the delay is introduced between these components when processed through the RF and IF stages. In order to feed a tape recorder with a signal suitable for recording, one must take into account the differential delay of 0.2 microseconds between chrominance and luminance components, which occurs on the video demodulator due to the influence of the HF and IF stages. The delay line 138 is used for this purpose, so that the signal recorded on the tape again corresponds to the usual standardized video signal (eg NTSC signal) in which there is no significant differential delay between luminance and chrominance components.

The amplifier transistor 139 amplifies the signal mixture fed to its base and forwards the amplified signal to the base of a downstream amplifier transistor stage 140 , which is also designed as an emitter circuit and further amplifies the signal mixture to a level suitable for being fed to the input of a buffer amplifier transistor stage 145 . The collector of the buffer transistor 145 is connected to ground via an operating resistor 146 and its emitter is connected to the operating voltage source + Kx via a negative feedback resistor 147. The composite video signal is AC coupled through a large capacitor 148 to an output jack 150 for video recording. The output jack 150 can be connected by a cable or other suitable arrangement to the input of a tape recorder for recording the video signal.

With the receiver equipped with the additional circuit described above, transmitted RF signals, which have been demodulated to a video signal in the normal manner in the receiver, can be recorded by means of a tape recorder. The audio part of the receiver is switched on via the switch 181 in its position shown in broken lines so that the audio signal is fed to a final amplifier transistor stage 155 after demodulation by the audio demodulator of the receiver. The transistor 155, which is connected as an emitter follower, has its emitter coupled via a capacitor 156 to an output socket 157 for sound recording so that the accompanying sound can be recorded together with the video signal by means of a suitable recording device, for example one with helical scanning.

Fig. 4 shows a horizontal oscillator circuit. The circuit includes a triode 150, which is coupled with its grid to a horizontal phase detector circuit with two diodes 151 and 152. The horizontal synchronizing pulse from the synchronizing signal separating stage 61 (F i g. 3) is connected via a capacitor 153 to the junction point of the cathodes of the diodes 151 and 152 supplied The horizontal oscillator signal is supplied to the anode of the diode 151 via a capacitor 180 . The signal amplitude is divided by means of a capacitor 181 in such a way that it receives the correct level. The diodes generate a DC control voltage on the output side, which corresponds to the phase difference between the horizontal synchronization pulses and the oscillator

gate signal is proportional

The control voltage is fed to the grid of the triode 150 via a resistor 157. Filtering at the grid of triode 150 by means of a resistor coupled between the grid and the ground capacitor 158 in conjunction with the parallel therewith connected selectively AEC series member consisting of a capacitor 160 and a resistor 161. The appearing between the anode and cathode of the triode 150 reinforced Control voltage is fed to the horizontal oscillator stage via the series connection of a potentiometer 163 and a resistor 164. Two resistors 163 and 164 are connected between the cathode of the triode 150 and the grid of a further triode 165. The triode 165 belongs to the horizontal oscillator stage, which operates with feedback between the anode and grid of the triode via a tapped coil 168 and a capacitor 170. By means of the control voltage coupled to the grid via potentiometer 163, the horizontal oscillator is phase-synchronized with the horizontal synchronization pulses

A matched parallel resonance circuit with a coil 177 and a capacitor 178 is located between the cathode of the oscillator triode 165 and ground produces a relatively narrow bandpass filter for the oscillator in the case of RF reception

If the recipient, as in connection with F i g. 3 describes external video signals is switched to reception, is the switch 82 in the position shown in Figure 4 position, the lying parallel with the resistor 161 resistor is turned off 123 so that the filter effect is reduced, and thereby faster transitions or changes of the control DC voltage can reach the grid of the triode 150 . At the same time, when the switch 82 is in this position, the tuned circuit with the coil 177 and the capacitor 178 is short-circuited by the cathode of the oscillator triode 165 being connected to ground control voltages can be regulated with sharper or faster transitions from level to level. In the video monitor mode, the oscillator can therefore change its phase and frequency much more quickly in accordance with the control information received from the phase detector, so that it can follow relatively rapid disturbances in the phase of the horizontal synchronization pulses, as can occur when playing back from the tape.

When the switch 82 is switched to RF reception, the resistor 123 is parallel to the resistor 161, so that the total resistance of the parallel connection is correspondingly lower and the control signal for higher frequencies at the grid of the triode 150 is more attenuated. In this case, the parallel resonance circuit coupled to the cathode of the triode 165 is also switched on, so that the control range of the horizontal oscillator is correspondingly narrowed.

Below are, for example, ratings for various circuit elements in the arrangement indicated according to Fig.3. Circuit elements included in

ίο this list are not listed, have those in the Values indicated in the drawing.

resistance 20th Kitchen sink 40 (changeable) 50 diode 87 35000hm 90 10 ohms 92 56000hm 93 56000hm «(Changeable) 94 33000hm 25th transistor 55 99 15000hm 102 3300hm 106 82 ohms 107 18 ohms 109 2200hm 30th
capacitor 126 7500hm 127 2700hm 130 1800hm 135 8200hm 35 136 3300hm 146 82 ohms 147 39 ohms 88 25 μΡ 91 0.01 μΡ 101 39 pF 108 220OpF 124 56OpF 131 47OpF 132 33OpF 148 500 μΡ 95 in response with capacitor 101 at about 2.5-3.1 MHz 100 120 μΗ 128 in response with capacitor 131 at approx. 4-4.5 MHz 89 2N3694 96 2N3694 105 2N3644 112 2N3694 125 2N3694 139 2N3644 140 2N3694 145 2N3644 155 2N3694 111 Silicon diode, z. B. FD222

In addition 5 sheets of drawings

Claims (6)

Patent claims: 1. Television receiver with an automatic gain control circuit as well as with a selective one actuatable arrangement for switching the receiver to a first operating mode, in which at Reception of a modulated with a television signal composite RF carrier reproduced a television picture is, characterized in that by means of the selectively operable arrangement of Receiver also has a second mode of operation in which it responds directly to an external source (21, 22, 23) originating video signal without RF carrier responds, and / or to a third operating mode, in which the receiver a video signal in the form of a composite television signal for the outside Use supplies, is switchable, the automatic gain control circuit (16) in the second and / or the third operating mode to the external video signal or to an internally provided video signal Acts on the video signal. 2. Television receiver according to claim 1 with a signal processing circuit which is modulated from a video RF carrier signal generates a demodulated video signal, as well as with a video amplifier, which amplifies the demodulated video signal and the picture reproducing device of the receiver wherein the automatic gain control circuit controls the gain of the signal treatment circuit regulates according to the amplitude of the demodulated video signal, characterized in that that the selectively operable arrangement the following devices for operation in the second Operating mode contains: An amplifier (26) with adjustable bias voltage, the input of which is the external video signal can be supplied and which supplies an amplified version of the external video signal at its output; a first actuator (27) which, in the actuated state, the output of the bias voltage controllable Amplifier coupled to the input of the video amplifier (12); on to the signal handling circuit (11) coupled second actuator (32), which upon actuation of the first actuator the Signal handling circuit switches off; and one between the automatic gain control circuit (16) and the bias voltage controllable amplifier (26) coupled arrangement (30), which at Actuation of the first actuator (27) the automatic gain control circuit in the Position sets the bias of the bias adjustable amplifier according to the DC level of the video signal in the video amplifier (12) to regulate. 3. Television receiver according to claim 1 with a synchronization signal separation stage, which is from the received Signalgemifch derives a synchronization pulse and a phase detector, the one Horizontal oscillator of the receiver is assigned, feeds, such that by comparing the phase and frequency of the synchronization pulse with the oscillator signal a control voltage is generated, which is fed to the oscillator via a filter network, in such a way that by regulating the phase of the Oscillator signal this is phase-synchronized with the synchronization pulse by an arrangement (82, 123) which is coupled to the filter network (158, 160, 161) and which is activated upon actuation supply of a first actuator (27) of the selectively operable arrangement the amount of Filtering of the control voltage is reduced when the external video signal is transmitted to the video amplifier (12) of the Receiver is supplied. 4. Television receiver according to one of the preceding claims with a signal processing circuit, the upon receipt of an RF carrier, which by a broadband luminance components and modulates composite television signals containing higher frequency narrowband color components delivers the composite television signal at the output of a video demodulator, characterized in that, that the selectively operable arrangement the following devices for operation in the third Operating mode contains: A first circuit (125) coupled to the video demodulator (11), which at Receipt of the composite signal acts selectively in such a way on the chrominance components that their Properties in relation to the luminance components are changed so that at the output of this first circuit a signal mixture which is essentially unaffected by the signal processing circuit is obtained; and an arrangement (139,140,145) coupled to the first circuit, which the Signal fed to a consumer output for external use. 5. A television receiver according to claim 4, wherein the video demodulator is the composite video signal a chrominance amplifier and a luminance amplifier, both of which are connected to the image display device of the receiver are coupled, characterized in that the first Circuit an equalization network coupled to the output of the video demodulator (128, 131) to selectively increase the amplitude of the chrominance components compared to the amplitude of the Contains luminance components; that a delay line (138) is coupled to the first circuit is which at its output a predetermined differential delay between the luminance components and the chrominance components generated such that a composite signal having a relatively constant delay distribution with the frequency is obtained; and that to the delay line an arrangement (139, 140, 145) for Amplification of the signal coupled to a level suitable for the feed line to the consumer output is. 6. Television receiver according to one of claims 1 to 3 with a signal processing circuit, which at Receiving a composite television signal containing luminance and chrominance components modulated RF carrier provides a demodulated composite video signal, with a Video amplifier containing a delay line that amplifies the composite signal and the luminance components delayed and fed to the image reproduction device of the receiver, with a chrominance amplifier, the at least one input in common with the video amplifier and amplifies the chrominance components and the image reproducing device feeds, and with an automatic gain control circuit that is under control by synchronizing pulses contained in the composite signal a corresponding amplitude Control signal for regulating the amplification of the signal handling maintenance according to the size ße this control signal is generated, characterized in that that the selectively operable arrangement following facilities for operation in the second mode of operation includes; a voltage controllable amplifier (89), the input (86) of which the external composite television signal is zuieitbar and an amplified version of this at its output Mixed signal supplies; a circuit (96, 105) coupled to the output of this amplifier, which by selectively reducing the amplitude of the chrominance components versus the luminance components on the output side supplies a second composite signal in which the chrominance components have a different approach to the luminance components than in the first composite signal; a first actuating device (83) which, when actuated, the output of said circuit (96, 105) couples to the common input of the luminance and chrominance amplifiers; a second device (80) coupled to the signal processing circuit, which upon actuation of the first actuating device switches on the signal processing circuit; one to the delay line of the video amplifier coupled third device (74, 75), which upon actuation of the first actuating device the delay of the delay line (76, 120) and consequently the Decreased delay between luminance and chrominance components; and one between the automatic gain control circuit (60) jo and the bias voltage controllable amplifier (89) coupled fourth device (112) which, upon actuation of the first actuating device, the automatic Gain control circuit enables the bias of the bias controllable amplifier to change according to the size of the synchronization pulses in the external composite television signal.