DE2355399C3 - Demodulator circuit for an amplitude-modulated carrier wave superimposed by interference pulses - Google Patents

Description

The present invention relates to a demodulator circuit according to the preamble of the patent claim 1.

From US-PS 27 17 920 a noise blanking circuit for a television receiver is already known in which, in addition to a conventional video demodulator consisting of a diode, an additional auxiliary video demodulator is provided. The output signal of the HiIFs-Vi deodemodulators is fed to a threshold and inverter circuit, and the resulting inverted signal, which corresponds only to the peaks of the glitches in the video signal exceeding the threshold, is combined with the video signal, so that the inverted glitches are the non-inverted glitches in the compensate demodulated video signal. In such a noise blanking circuit, it is also known to widen the pulses used for eliminating interference so that secondary interference pulses can also be eliminated which are caused by overshoots from the interference pulses received in the video signal (DT-AS II Ii 002).

In the known circuits mentioned above, the video demodulator is an envelope demodulator. However, an envelope demodulator is useful in certain applications, e.g. B. as a video demodulator in one Television receiver, a synchronous demodulator is preferable to the one with the support raised or as a product demodulator can work because such synchronous demodulators have better linearity, a

Are susceptible to cross-modulation and have a higher immunity to interference. Synchronous video demodulators are therefore already used in commercial television receivers. The problem of the 920 KHz beats between the sound and the color carrier, which can lead to herringbone-like disturbances in the television picture, can be dealt with much better by using a video synchronous demodulator fewer demands are placed on the filter, which has a better phases of ^ "in the video intermediate frequency amplifier and ⁰ a better transient response in Farbdemodulator- and color enhancers part of a color television receiver result.

A video synchronous demodulator does not behave as well as an envelope demodulator with regard to interference pulses. An envelope video demodulator rectifies the glitch peaks, with in the black direction running interfering signals arise from a viewer of the resulting television picture in the generally not be perceived as annoying. A Synehron video demodulator, on the other hand, directs the interference pulses not the same, but generates interference signals in the middle of the band when they are demodulated, theirs Have a center of gravity at around 2 MHz and run alternately in the black direction and white direction. In the Components of these glitches running in white direction are generally recognized by the viewer of the television picture perceived as much more disturbing than the interference signal components running in the black direction. In addition, the synchronous demodulation of interference pulses can lead to the whiter-than-white range outgoing interference impulses cause a defocusing of the electron beam, which is called "blooming" and increase the size of the resulting white clutter in the image.

Measures are already known for synchronous demodulation of a video signal occurring and running in the white direction largely to render ineffective. The basic principle of the circuit arrangements previously used for this purpose is in US-PS 28 61 180 described: The parts of the am on the whiter-than-white area extending Output of a synchronous video demodulator appearing video signal are rectified, and the Video signal is suppressed by cropping the parts reaching into the whiter-than-white area. at Television systems that operate with positive modulation, as in Great Britain, can move into the whiter-than-white range Extending interference pulses are demodulated and those extending in the black direction Pulses can be inverted using the envelope video demodulators for the impulse disturbances extending into the whiter-than-white area use in conjunction with synchronous video demodulators.

With the direct demodulation of interference pulses that reach into the whiter-than-white range, and at the conversion of such impulses into impulses that run in the black direction, however, occur certain Difficulties arise: The thermal noise that superimposes the carrier oscillations to be demodulated must not exceed the demodulation threshold value too often during predominantly white parts of the image, otherwise the picture is covered with many small black spots. With such an arrangement is the threshold of the r.chwell value demodulator yes in the whiter-than-white area. Signals that exceed this threshold are inverted so that they then run in the black direction. If the welding value is close to the white value, the However, the threshold value is often exceeded during predominantly white parts of the image due to the thermal noise will. As a result, the video signal is often inverted undesirably, thereby causing the disturbing black spots appear. This difficulty cannot be remedied by adjusting the threshold value adjusts to a value even further in the white range, since this measure increases the effectiveness for interference that only slightly extends into the whiter than white range and stronger television signals are superimposed is deteriorated. In more expensive television receivers of this type, the threshold value the interference signal demodulation is automatically adapted to the signal strength.

The present invention is based on the task to avoid the above-described disadvantages of the prior art and an amplitude demodulator circuit indicate that is largely insensitive to interference pulses and thermal noise as well as a simple structure and reliable operation.

This object is achieved in a demodulator circuit with the features of the preamble of the claim 1 solved according to the invention by the characterizing features of claim 1.

The demodulator circuit according to the invention is insensitive to interference pulses and thermal Noise, it is also characterized by its relatively simple structure, and all advantages are retained, resulting from the use of a synchronous video demodulator.

The following are exemplary embodiments of the invention explained in more detail with reference to the drawing. It shows

F i g. 1 is a block diagram of a television receiver incorporating a demodulator circuit according to an embodiment of the invention,

F i g. 2a to 2g graphical representations of the course of signals in the television receiver according to F i g. 1 occur, and

F i g. 3 shows a circuit diagram of a video demodulator according to a further exemplary embodiment of the invention.

In Fig. 1 shows a television receiver 100 , to which a television signal is fed via an antenna 101, in a greatly simplified manner. The television receiver 100 contains a high-frequency amplifier 103, a frequency converter 105 in a mixer and oscillator stage, a video intermediate frequency amplifier 107, a video synchronous demodulator 109, a sync pulse separator 111 connected to its output, a line deflection generator 113, an image deflection generator 115 with Line and image deflection coils 117 are coupled, a picture tube 119, an AGC circuit 120 for automatic gain control of the amplifiers 103 and 107, a video or picture display part 121 coupled between the output of the synchronous demodulator 109 and the picture tube 119 , which is usually a luminance amplifier and im In the case of a color television receiver, comprises a color demodulator and color amplifier. The circuit arrangement described so far is conventional and customary! not to be further explained.

The television receiver 100 shown also contains an envelope demodulator 123, which operates as an auxiliary video demodulator for the carrier oscillation from the intermediate frequency amplifier 107 . The demodulated video signal from the envelope demodulator 123 is fed to the input circuit of a threshold value detector 125 which is responsive to drifts of the video signal which exceed its threshold value in the black direction. The threshold value corresponds to the black value or a signal value lying in the blacker-than-black range of the video signal. When the threshold value is exceeded, the threshold value detector 125 generates a blanking signal for a selective, controlled blanking circuit 127.

The controlled blanking circuit 127 couples the output circuit of the video synchronous demodulator 109 to the image display part 121 as long as the threshold value detector 125 does not supply a blanking signal to the blanking circuit 127. However, when the threshold value detector supplies a blanking signal to the blanking circuit 127 , a predetermined reference level is supplied from a source 129 to the input circuit of the image reproducing part 121. In various embodiments of the present invention, the predetermined reference level can be selected so that it corresponds to a blacker-than-black value, the black value or a gray value of the video signal in which it is used. In this way, the subjective effect of the noise signals in the picture, which is generated on the screen as a result of the modified video signal, is less perceptible than due to a video signal in which whiter-than-white values occur. If there are no noise pulses, the demodulated video signal is passed from the video synchronous demodulator 109 via the blanking circuit 127 to the image display part 121. The receiver 100 then works like a conventional receiver with video synchronous demodulation.

If the carrier oscillations which 127 supplies the intermediate frequency amplifier to the demodulators 109 and 123, contain glitches, as 109 says the video synchronous on to a demodulated video signal containing White-than-white areas. The envelope demodulator 123 responds to this at the same time and generates a demodulated blacker-than-black video signal so that the threshold value detector 125 supplies blanking signals to the blanking circuit 127 . Then the predetermined video signal level from the source 129 is applied to the input circuit of the picture reproducing part 121 in place of the demodulated whiter-than-white video output signal of the video synchronous demodulator 109

F i g. FIG. 2 shows waveforms as they occur at various points in the FIG. 1 shown television set occur.

^; In Fig. 2a shows a typical line interval of the modulated video intermediate frequency carrier wave as it is fed to the demodulators 109, 123 from the video intermediate frequency amplifier 107. Only the envelopes of this modulated carrier oscillation are shown in outline, since the actual fluctuations of the carrier oscillation cannot be clearly reproduced due to the time scale shown. A glitch 50 occurs between times to and if. For the sake of clarity, the time scale of the representation is stretched in the area of the interference pulse

F i g. 2b shows the addressing of the synchronous demodula

gate 109 to the modulated video intermediate frequency carrier wave according to FIG. 2a. The interference pulse 50 creates a pair of pulses or doublet 55 with a part 56 running in the black direction and a part 57 running in the white direction. In the case of interference pulses of longer duration, the demodulator 109 supplies a multiple damped oscillation. The whiter-than-white tcil 57 oscillating below the white level 58 causes strongly perceptible disturbances.

ίο F i g. 2c shows how the envelope demodulator 123 responds to the modulated video intermediate frequency carrier wave according to FIG. 2a responds. The interference pulse 50 is rectified, as a result of which a pulse running in the black direction is generated without any noteworthy parts running in the white direction. This pulse is fed to the threshold value detector 125 , the threshold value level of which is at the black value or a blacker-than-black value.

In Fig. 2d the blanking signal pulse 65 is shown, which is generated by the threshold value detector when the threshold value passes through the black direction Pulse 60 is exceeded.

F i g. 2e shows a video signal as it can be output by the blanking circuit 127. Its Veilauf is similar to that of the output signal of the synchronous demodulator 109, which is shown in FIG. 2b is shown, with the exception that the signal during the time interval between the times ίο and fr is at a reference level 72 which is equal to the black level. In Fig. 2f shows the video signal as it is supplied by the selective sampling circuit 127 when the reference level 77 at which the signal is held during the time interval between the times to and tr corresponds to a gray value. F i g. 2g shows the video signal at the output of the selective blanking circuit 127 when the reference level 82 corresponds to a blacker-than-black value.

In the one shown in FIG. 1, the television receiver 100 shown in FIG. 1 is predominantly white information far removed from the threshold value of the threshold value detector 125 , since its threshold value is at a black value or a blacker-than-black value. Thermal noise at the white level will therefore not be sufficient to cause the threshold value detector 125 to deliver a blanking signal. This is shown in FIGS. 2a and 2c shown. The thermal noise 51 during a part of the video intermediate frequency carrier wave which is in the white range according to FIG. 2a gives rise to demodulated, thermal noise pulses 61 (see FIG. 2c) in the output signal of the envelope demodulator 123 , which are far below the threshold value of the threshold detector corresponding to the black value or a blacker-than-black value. In contrast, during predominantly black information, the thermal noise pulses can cause the threshold value detector 125 to generate a blanking signal. However, if the predetermined video level from source 129 is close to black, the resulting blanking will not be noticeable in the picture.

Because the interference pulses running in the white direction during predominantly black information If the information is predominantly black, the threshold value detector should be more noticeable the correction of the video signal with as small as possible

* 5 cause delay. lies the swell of the Threshold detector, as is the case with the present invention, is relatively close to the black level instead of close to the white value, this makes it easier to

Solution of impulse disturbances in the presence of predominantly black information, since only a relatively small one Increase in interference is required to reach the threshold. Accordingly join Television receivers making use of the present invention will not experience white interference in the black areas of the image.

The use of separate envelope curve and threshold value detectors 123 and 125 (FIG. I) is made possible it, the sound part 131, which feeds sound-frequency signals to the loudspeaker 133, with sound-intermediate frequency carrier oscillations from the envelope demodulator 123 to be fed. This is particularly advantageous if the video demodulator 109 is a synchronous demodulator that arbeilet with an oscillator, which by automatic phase and frequency control is synchronized with the received signal. With a synchronous demodulator of this nature would occur in speaker 133 during the onset or suspension of synchronism with the modulated video carrier wave an annoying superimposition whistle occurs, which cannot happen when using an envelope demodulator (such as 123).

A synchronous demodulator 109 with a raised carrier, in which the unmodulated carrier oscillation by limiting and filtering the modulated video intermediate frequency carrier is recovered can provide modulated sound carrier waves for the sound portion 131 without the aforementioned problem of overlay whistling occurs. In a television receiver with such a synchronous demodulator the envelope detector 123 and the threshold value detector 125 can be made by the same circuit arrangement are formed by applying such a bias voltage to the envelope detector 123 that it only responds to impulses of the video intermediate frequency carrier wave, the amplitude of which is a exceeds a certain threshold.

F i g. 3 shows an embodiment of the present invention with a synchronous demodulator in which the modulated carrier waves are limited and then passed through a bandpass filter to unmodulated To get carrier waves, whereupon the modulated carrier waves with the unmodulated Carrier vibrations are product-demodulated. The intermediate frequency video signals applied to input terminals 200 are connected to the bases via a dual tuned transformer input circuit 201 supplied by transistors 203, 205 connected as emitter followers

The anti-phase video intermediate frequency signals at the emitters of the transistors 203, 205 are fed to an emitter-coupled differential amplifier 207 which contains transistors 209 and 211. The output circuit of the amplifier 207 is formed by a bandpass filter 213 which is matched to the video carrier frequency and which filters out the limited video carrier oscillations which are fed to the bases of emitter follower transistors 215, 217 in antiphase. The antiphase carrier oscillations pass through series-connected emitter follower transistors 215, 219 or 217, 221 and are fed from the emitters of the transistors 219 and 221 to a product demodulator 225 as a switching signal

The product demodulator 225, which is used as a video synchronous demodulator, is also with antiphase Intermediate frequency video signals - i.e. with modulated Video carrier waves - fed from the emitters of transistors 203 and 205, respectively. The demodulated Video signals appear symmetrically between output terminals 227, 229 of the product demodulator 225 and are fed to an electronic de-balancing circuit 231 which is disclosed in US Pat 36 41 448 can be switched, the balanced video signals combined and an unbalanced video signal to the base of a transistor 233 supplies.

The circuit arrangement described so far in FIG. 3 illustrates a video synchronous demodulator. The video intermediate frequency carrier at the emitter of transistor 205 is also sent to the base a transistor 235 operating in the emitter circuit. The collector of transistor 235 provides amplified Video intermediate frequency carrier waves to the base of a transistor 239, its base-emitter junction represents the rectifier of an envelope demodulator 240. The emitter of the transistor 239 is connected to a reference voltage of + 11 volts via a resistor 241. That demodulated Video signal is composed by a capacitor 234 and the collector-base capacitance of transistor 225 integrated with the resistor 241 and freed from the last remnant of the carrier shrinkage.

The demodulated signal is inverted via a transistor 245 acting as an emitter follower Amplifier 250 supplied with the current gain factor 1, which is constructed in accordance with US Pat. No. 3,531,730 and an output transistor 251. The collector load of the output transistor 251 of the inverting Amplifier 250 has a variable threshold setting resistor which is a Adjustment of the rest potential at the connection of the collector of the transistor 251 to the base of a Transistor 260 allows.

The transistor 260 is the threshold value detector, the potential at its collector to the emitter potential stuck when the demodulated by the video demodulator 250 and its base over the inverting The video signal supplied to amplifier 250 is large enough to pass its base-emitter junction in the forward direction to switch to the conductive state, d. i.e. when glitches occur. When transistor 260 is in the normal, non-conductive state, it has no influence on the video signal from the video synchronous demodulator of the circuit arrangement occurs at the emitter of transistor 233 and via the resistor 26 i is coupled to the base of the emitter follower output transistor 263. When the transistor 260 conducts when interference pulses occur, the base voltage of transistor 263 is at + 2Vbe potential clamped to the emitter electrode of transistor 260. That is, the transistor 260 and the Resistor 261 form a keyed clamping circuit 265, which is connected to that of the envelope curve demodulator 240 The selectively blanked video signal at the base of transistor 263 responds is coupled to the output terminal »OUTPUT« by the emitter follower effect of transistor 263, which is connected to the emitter of this transistor 263

In operation, the circuit arrangement shown, the video signal is clamped during the occurrence of interference pulses in a dark shade of gray This allows both the Synchronimpulsäbtrennstufe 111 and the image-reproducing portion 121 connected to the terminal "OUT", without the risk that selective by the Glitch off

6O96S3 / 3O7

erroneous sync pulses to the sync pulse separation stage 111 arrive. The sound part 131 can also be connected to the transistor 263, see above that he receives a frequency-modulated subcarrier-Tonin-Formation, which as a component of the signal the terminal »OUTPUT« is also available.

For this purpose 4 sheets of drawings

Claims (8)

Patent claims: 1. Demodulator circuit for amplitude-modulated signals, with a first amplitude demodulator, the input circuit of which can be supplied with an amplitude-modulated carrier oscillation, possibly superimposed by interference pulses, from a carrier oscillation source and whose output circuit supplies a first demodulated signal which contains a first interference signal if interference pulses are present in the carrier oscillation , which at least partially has a predetermined first polarity with respect to the polarity of the first demodulated signal, and with a second amplitude demodulator, characterized in that the input circuit of the second amplitude demodulator (123, 125) connected to the carrier vibration source has a second demodulated signal in its output circuit as well a second interference signal corresponding to the interference pulses, which has a predetermined second polarity opposite to the first polarity with respect to the second demodulated signal, and that the Au The output circuit of the first amplitude demodulator (109) is selectively coupled to a load circuit (111, 121) via a circuit part (127) which responds to whether the second interference signal in the direction of the second polarity exceeds a predetermined threshold value. 2. Demodulator circuit according to claim 1, characterized in that the carrier oscillation source supplies a video Zwischer.frequency signal to the two amplitude demodulators (109, 123) , which supply the corresponding demodulated video signals containing synchronizing pulses, and that the consumer circuit has a synchronizing pulse Abirennstufe (lll ) contains. 3. Demodulator circuit according to claim I, characterized in that the carrier oscillations contain a frequency-modulated vibration component and that the consumer circuit a Device for demodulating the frequency-modulated carrier oscillation component included. 4. Demodulator circuit according to claim 1 for a television receiver with a video synchronization modulator which generates a video signal for a video signal processing circuit and a synchronous pulse separation circuit by demodulating a video signal mixture, characterized in that the second demodulator (123, 125) has a blanking signal corresponding to the emigration of the envelope of the video signal mixture, which exceed a predetermined threshold value, and that the circuit arrangement (127) between the video synchronous demodulator (109) and the video signal processing circuit (121) is sounded and controlled by the blanking signal to interrupt the supply of the video signals to the video signal processing circuit. 5. Demodulator circuit according to claim 4, characterized in that the second amplitude demodulator contains an envelope demodulator (123) and a threshold value detector (125) whose input is coupled directly to the output of the envelope modulator (123) and whose output is coupled to the blanking circuit (127) and that the output of the envelope demodulator (123) with a sound part (131) of the television receiver pelt is. 6. Demodulator circuit according to claim 4, d; characterized in that the blanking circuit m a video reference level source (129) coupled un an electrically controlled selection circuit (127) em holds, the latter having a first input coupled to the video synchror demodulator (109) and a second input coupled to the video reference level source (129) having the Austastsi gnal fed control input and a de gekoppeltei with video processing circuit (121) output and couples the first and second input of the video processing circuit (121 or in the absence of blanking pulses EXISTING densein. 7. Demodulator circuit according to claim 6, characterized in that the video reference level is different from the blacker-than-black value of the video signal fed to the video processing shaft (i21) and that the blanking circuit (127) between the video synchronous demodulator (109) and the synchronizing pulse separator (111 ) and between the video synchronous demodulator (109) and the video processing circuit (121). 8. Demodulator circuit according to claim 4, characterized in that the blanking circuit (127) is provided with a reference level circuit (129) and a keyed clamping circuit (265) which clamps the video signals for the video processing circuit (121) depending on the blanking signal at the reference level.