DE2637013A1 - Drop=out detector for FM carrier in video recorder - has demodulator with special characteristics to detect drop=outs irrespective of direction and frequency - Google Patents

Abstract

The drop-out detector for a frequency modulated carrier wave detects in a simple way all drop-outs irrespective of their direction, frequency and the instantaneous amplitude of the video signal, and always produces a pulse when a drop-out occurs. It uses a demodulator whose demodulation characteristics are relatively flat inside the wanted frequency range (11) and relatively steep outside it. The characteristic curve passes through a maximum and is symmetric about the centre frequency of the wanted range. The ends of the wanted range have roughly the same amplitude.

Description

Dropout detection circuit for a frequency modulated

Carrier, especially for a video recorder, when recording of a video signal, for example on a magnetic tape or optical disc, is known the signal recorded in the form of a frequency-modulated carrier, since then through an amplitude limitation, amplitude fluctuations can be largely eliminated can. In such recording devices, defects in the recording layer result in gaps in the sampled modulated by foreign bodies and a variety of other influences Carriers that in the reproduced picture lead to signal dropouts in the form of more or less lead long horizontal strips. These errors are known as dropouts.

To reduce such errors, it is known (DT-AS 12 02 315), in an amplitude rectifier from the modulated carrier when one occurs Dropout to gain a switching pulse and thus the signal during the dropout away to switch to a substitute signal. The substitute signal path supplies, for example, that Signal of a previous line by means of a delay device for a or several line durations. The substitute signal can also be one that corresponds to a gray value Fixed DC voltage or a voltage obtained by integrating the video signal be.

Such circuits therefore require a detector for detection a dropout and for generating the switching pulse.

In a known circuit (DT-OS 25 25 074) the output signal of the FM demodulator except for a low-pass filter for obtaining the useful video signal second low-pass filter with a significantly larger bandwidth than that of the first low-pass filter fed. The output signal of this second low-pass filter is used by a maximum comparator and fed to a minimum comparator. These two comparators each provide one Impulse when the video signal at the output of the second low-pass filter has a minimum value falls below or exceeds a maximum value.

The output voltages of the two comparators are added, and the sum serves as a switching pulse for switching the signal path to the substitute signal path when a dropout occurs.

In this circuit, the demodulated signal must have a large bandwidth to be given to the comparator. Two comparators are necessary to determine the Capture dropouts in both directions. In addition, the generated switching pulse can be extended by additional stretch circuits so that it extends the signal path switches to the substitute signal path for a sufficient period of time.

The invention is based on the object of a simplified circuit to create all of the dropouts regardless of their direction, frequency and recognizes the instantaneous amplitude of the video signal equally well and in all Cases a faultless switching pulse is generated.

This object is achieved by the invention specified in claim 1. Advantageous further developments of the invention are specified in the subclaims.

The solution according to the invention is therefore specially designed for the extraction of the switching pulse from the dropout a separate FM demodulator with a special one Characteristic created, the on the useful signal as little as possible, however responds perfectly to the dropouts in all cases. It is then only a threshold value circuit necessary for dropouts in both frequency directions. The one in the known circuit The low-pass filter used with a large bandwidth is not necessary. Also the at The widening of the switching pulses used in the known circuit is not required. Another major advantage is that the dropouts occur at all amplitudes of the useful signal can be detected equally well.

The invention is illustrated below with reference to the drawing using an exemplary embodiment explained. FIG. 1 shows the general problem and the known ones Circuits occurring disadvantages, Figure 2a, b structure and characteristic of a for implementation the invention suitable demodulator, Figure 3a, b the same for another demodulator, FIG. 4 curves to explain the improved results achieved by the invention Dropout detection and FIG. 5 shows a practical embodiment of the invention.

In the drawing, the symbols used have the following meanings: fd = frequency of the FM carrier in the event of a dropout td = duration of a dropout f = frequency of the FM carrier f1 = frequency of the FM carrier for full level, i.e. maximum amplitude modulated video signal f2 = frequency of the FM carrier for black level fo = resonance frequency of the resonant circuit LC in FIG. 3 TP = low-pass filter after the FM demodulator t = rise time of the low-pass filter TP t 2- Delay in the occurrence of the switching pulse U2 ~ output voltage of the FM demodulator.

In Figure 1, the FM carrier modulated with the video signal contains during its instantaneous frequency f1 and one each during the instantaneous frequency f2 Dropout with frequency and duration td <ta or td> ta. There is a problem in the fact that dropouts that go to low frequencies are often in the upper stroke range and vice versa. Figure 1 shows that it is then essential to reach the switchover threshold larger and longer interference pulses are required than if, for example, a deep Frequencies going dropout is in the lower stroke range. For this reason, at known circuits, the video signal very broadband to the comparison circuit are given. So that such a filter still sufficiently suppresses the FM carrier, it must be very steep, which means a lot of effort. The one shown in FIG Cut-off level is the level at which the switching pulse is generated due to a dropout will. The frequency fd is below the frequency corresponding to the synchronous level. The first dropout shown at the top left in FIG. 1 takes place during the full level corresponding frequency f1. The second dropout is in the range of the black level corresponding frequency f2. The illustration shows that because of the rise time ta of the low pass the first short dropout the threshold value for the separation of the switching voltage (Cut-off level) not reached within the dropout period. The second short dropout reaches the threshold, however, so that the switching pulse shown in full is produced. This switching pulse begins with the delay t 1 and ends around the Time later than the actual short dropout.

The dropout duration would be so long that at the output of the FM demodulator the dropout level is reached (td> SO then a switching pulse is generated for both dropouts generated. These are shown in dashed lines in FIG. The one lying in the area f2 long dropout, however, generates a switching pulse that begins earlier and ends later, is therefore also more favorable for the dropout elimination than the one in area 1 same dropout.

In the invention is now for the detection of the dropout, so for the generation of the switching pulse, a separate FM demodulator is used, its Output voltage is flat in the frequency range assigned to the useful signal, e.g. has an extreme value.

Figure 2 shows the structure and the characteristic of such a demodulator. The FM carrier is from a terminal 5 to the carrier input 10 of a modulator 6 and also fed to the signal input 20 of the modulator 6 via a delay element 7. At the output terminal 9 of the low-pass filter 8 arises from the fact that the time t is selected in this way is that in the middle of the stroke range the phase rotation of the FM carrier is 1800, an output voltage U2 according to the characteristic curve according to FIG. 2b. The circuit according to figure 2a works on the principle of the transit time frequency demodulator. However, it lies the frequency deviation range 11, which corresponds to the useful video signal, is not on a straight line Part of the characteristic curve, but rather symmetrical to a tip. The point is created by that the limited FM carrier as a square wave on both inputs 10,20 des Modulator 6 is given. The modulator 6 consists of a circuit attached to its Output 30 supplies the product of the two voltages at inputs 10, 20. Included the voltage at the carrier input 10 acts as a switching function (+1, -1) with which the Voltage at signal input 20 is multiplied. Outside the stroke range 11, where the dropouts lie, the characteristic curve has one in both directions with increasing Distance from the lift area 11 increasing course. This demodulator that specifically is dimensioned for the generation of the switching pulses due to the dropouts, would be not suitable for obtaining the video signal from the FM carrier.

In FIG. 3b, the demodulator characteristic curve in the stroke range 11 has a flat one Course. This makes the output level more desirable for the normal video signal Way even more compressed, while the characteristic curve for outside the stroke range lying Frequencies, i.e. for dropouts, become steeper in a desired manner. About the Center frequency of the stroke range 11 tuned oscillating circuit L, C at the signal input 20 of the modulator 6 fulfills several tasks: 1. It generates a frequency-dependent one Phase rotation, which is approximately in the middle of the stroke range 11 at the frequency 0 0 °.

2. It sifts the FM carrier, which is limited in amplitude, so that at the signal input of the modulator, the FM signal is a sinusoidal oscillation. That causes the extreme value of the demodulation characteristic is not formed as a peak.

3. It offers an inexpensive comparison option.

The resonant circuit CL is strongly damped, so that the phase rotation in Stroke range is relatively small, e.g. +200.

The amplitude curve of the signal is therefore correspondingly flat at input 20 within the stroke range. That, in turn, is important for the flat Course of the characteristic curve according to FIG. 3b.

The tuning of the resonant circuit takes place in such a way that the synchronous level just a little lower than the full level.

FIG. 4 shows the signal profile for one line for an image whose left half is white and its right half is black, namely Figure 4a for a normal known FM demodulation and FIG. 4b with demodulation in one FM demodulator sized according to the invention. There are a total of four dropouts 1,2,3,4 drawn. The separation level 1 and 2 mean the level at which the switching pulses be generated. The four dropouts 1-4 shown are so short that during the rise time of the low pass the dropout level is not reached (td <ta) It can be seen that from the according to Figure 4a normal demodulated Signal is only recognized every second short dropout, although two threshold circuits can be used with cut-off level 1 and cut-off level 2. In the demodulator according to the invention, which supplies the signal shown in Figure 4b, however, each dropout is detected with only one threshold value circuit, since all dropouts 1-4 exceed the same threshold in the same direction.

In practice, when setting the threshold values or

when tuning the circuit LC, the pre-emphasis peaks at the signal jumps to be observed. For the sake of clarity, these are not taken into account here.

In FIG. 5, the signal coming from the scanner is frequency-modulated with the video signal FM carrier from terminal 12 via amplitude limiter 13 to the FM demodulator 14, which supplies the useful video signal 16 via the low-pass filter 15. This gets to the first input of the switch 17, which at its output at the terminal 18 of Dropouts exempt video signal 19 delivers. The top left entrance of the switch 17 shows the substitute signal path. The substitute signal is provided with a delay device 21 with the delay of the duration of n whole lines (n = 1,2,3) from the signal gained at terminal 18. In the event of a dropout, the switch 17 is activated by the switching pulse 22 switched to the upper position, so that the corresponding signal of a chronologically preceding line at terminal 18 instead of the dropout appears. The FM carrier from the output of the amplitude limiter 13 arrives also via line 23 to the input of the FM demodulator dimensioned according to the invention 24, which triggers the Schmitt trigger 26 in the event of a dropout via the low-pass filter 25, which in turn, the switching pulse 22 for switching the switch 17 is generated. At this The cut-off level for the switching pulse 22 is automatically on the circuit Synchronous level recorded. This takes place in that the switching pulse 22 after integration in stage 27 and gain in the amplifier to 25, de, ng of the FM demodulator 24 controls. The gain is dimensioned in such a way that a certain amount of impulses is always present have to be. However, this is smaller than all S-pulses. The clipping potential can therefore only lie on the synchronous level and use part of the S-pulses as Score dropout. These switching pulses are in the blanking intervals and can therefore easily rendered ineffective. This is done, for example, by blocking the switch with the blanking signal A from terminal 29. The proportion of the generated by the S-pulses Switching impulses will always be significantly larger than the proportion of the actual Dropouts. Therefore, the clipping potential is increased by the occurrence of dropouts hardly shifted, so that the dropouts are not blanked before the integration can be.

This automatic makes it possible to precisely match the cut-off potential To set the limit of the useful signal so that as many dropouts as possible are always detected, without the need for difficult adjustments and stabilizations.

The only remaining adjustment is made at the demodulator 24, e.g. on the resonant circuit L, C in Figure 3. This is to be adjusted so that the white level corresponding signal components do not quite reach the synchronous level (FIG. 4b). This results in an extremely simple and stable circuit, which records practically all dropouts visible in the picture.

The low-pass filter 25 can be used as a simple RC element with a relatively large Time constant (e.g. 0.8, us).

Despite this large time constant, the dropout pulse begins only slightly delayed, as the cut-off level is very high in relation to the dropout level is close to the useful signal level. However, the end of the switching pulse 22 receives the Desired long delay compared to the end of the dropout.

L e r s e i t e

Claims (9)

Claims 1. Dropout detection circuit for a frequency-modulated Carrier, especially for a video recording device, in which the carrier through the Useful signal is modulated over a certain range and in an FM demodulator is demodulated, from the output voltage of which in a comparison circuit a Switching pulse representing dropout is generated, characterized in that the Demodulator characteristic (Figure 2b, 3b) of the FM demodulator (24) within the stroke range (11) a relatively flat and outside of the lifting area (11) a relatively steep one Has course. 2. Circuit according to claim 1, characterized in that the characteristic curve runs through an extreme value within the stroke range (11) (FIGS. 2b, 3b). 3. A circuit according to claim 2, characterized in that the characteristic curve runs symmetrically to the center frequency (fO) of the stroke range (11) and at the two Ends of the stroke range (11) has approximately the same amplitude values. 4. A circuit according to claim 1, characterized in that the demodulator (24) contains a modulator (6) with a downstream low-pass filter (8) and the carrier the carrier input (10) directly and the signal input (20) via a delay stage (7) is supplied (Figure 2a). 5. A circuit according to claim 1, characterized in that the demodulator (24) contains a modulator (6) with a downstream low-pass filter (8) and the signal input via a resistor (R) to the carrier input (10) and via a parallel resonant circuit (L, C) is connected to ground. 6. A circuit according to claim 4 or 5, characterized in that the The carrier is fed to the modulator (24) in the form of a square wave. 7. A circuit according to claim 1, characterized in that at one Dropout compensation circuit for a video signal from a recording device of FM demodulator (24) a separate from the FM demodulator (14) for obtaining the useful video signal (16) is a separate demodulator (Figure 5). 8. A circuit according to claim 4, characterized in that the low-pass filter (8,25) consists of an RC element. 9. A circuit according to claim 7, characterized in that the input signal fed to the two demodulators (14, 24) via a common limiter (13) is (Figure 5).