DE19717310A1 - SECAM L and SECAM BG transmission norm recognition method - Google Patents

Abstract

The method involves multiplying a colour synchronisation signal of a colour-under colour signal with itself. One of the colour synchronisation signals is phase shifted by 90 degrees if it has a frequency above the frequency of a red colour synchronisation signal of a SECAM BG signal in colour-under frequency position. A phase shift of minus 90 degrees is carried out if the frequency is below the frequency of a blue colour synchronisation signal of a SECAM BG signal in colour-under frequency position. The product is low pass filtered, rectified, inverted alternating in display lines and integrated. The integrated signal is coupled to a first capacitance whose charge state indexes a colour signal of the SECAM BG transmission norm. The low pass filtered signal is integrated and the integrated signal is coupled to a second capacitance whose charge state indexes a colour signal of the SECAM L transmission norm.

Description

The invention relates to a method and an arrangement for detecting the SECAM L and SECAM BG transmission standards when playing a recorded on a recording medium using the color-under method Color image signal.

In recording devices for video signals, for example in video recorders VHS standard, the color signals of the color image signal to be recorded are mostly in the so-called color-under method recorded. This means that the Carrier frequencies of the color signal are converted to a lower frequency, which is below the carrier frequencies with which the brightness signal of the Color image signal is recorded. For example, the originally with Frequencies of 4.406 and 4.250 present carrier frequencies of the Color synchronizing signals of a SECAM BG signal before recording on frequencies down from 0.81 and 0.654 MHz. The same applies to Color image signals of other transmission standards.

It is an object of the invention to provide a method and a circuit arrangement create a recognition of SECAM L or SECAM BG transmission standards of such a reproduced color image signal, which in Color-under procedure was recorded. This detection is said to already before converting the frequencies of the color synchronization signals to standards Frequencies, so still in their color-under frequency position with which they were recorded.  

This object is achieved for a method according to the invention in that the color burst signal of the reproduced color under color image signal is multiplied by itself, one of the two color burst signals being subjected to a phase shift of +90 degrees if it has a frequency which is above the frequency of a red color burst signal of a SECAM-BG signal in color-under frequency position, or is subjected to a phase shift of -90 degrees if it has a frequency below the frequency of a blue color burst signal of a SECAM-BG signal in color-under Has frequency position,
that the product is subjected to low-pass filtering, rectification, an image line alternating inversion and subsequent integration,
that the integrated signal is coupled to a first capacitance whose state of charge indicates a color signal of the SECAM BG transmission standard,
and that the low-pass filtered signal is integrated and the integrated signal is coupled to a second capacitance whose state of charge indicates a color signal of the SECAM L transmission standard.

The color-under color image signal recorded on a tape, for example is particularly characterized in that the color signal or in it contained color burst signals are recorded with carrier frequencies, which lie below the carrier frequency of the recorded brightness signal.

When playing back a color-under color image signal recorded in this way its color burst signal multiplied by itself. The signal once in the original phase and once in the shifted phase multiplied together. The phase shift of one of the two signals is shown in Dependent on the frequency of the color synchronizing signal. Know that Color burst signal a frequency above that frequency, the one reproduced red color synchronizing signal in color-under frequency position of a  SECAM BG signal would have, this signal experiences one Phase shift of +90 degrees. On the other hand, indicates the color burst signal of the reproduced color-under-color signal at a frequency below the Frequency of the blue color burst signal of a reproduced SECAM BG color under color image signal, it experiences a phase shift of -90 Degree. The frequencies that are reproduced in a color-under frequency range SECAM BG color image signal is basically known. It is known on which frequencies the red or white color signal contained in a SECAM BG color signal Have blue color synchronous signals in the color-under frequency position. Depending on their known frequency position and the frequency position of the reproduced Color burst signal is the phase shift of the above described reproduced color image signal made in color-under frequency.

The resulting product of the reproduced color-under color burst signal in original or in a shifted phase position is first one Low pass filtering and subsequent rectification. About that In addition, the sign of the rectified signal is changed every other Image line inverted. This line-alternating inverted signal is then subjected to an integration. The signal resulting from the integration turns on coupled a first capacity. When multiplying the Color synchronizing signal of the color-under color image signal arise depending on the Sign of the phase shift of different mixed products. Becomes a Color image signal reproduced according to the SECAM BG standard, that indicates Color synchronizing signal from line to line alternately different frequencies, which also lead to the phase shift from line described above Line alternates. The product thus shows alternating from image line to image line Sign on, d. H. positive or changing from picture line to picture line negative values in the product. After its rectification, however the low-pass filtered product is inverted, so that in the subsequent integration the impulses are all the same again  Show signs. However, this only applies to a color image signal of the SECAM BG standard. If there is one, the pulses of the same polarity are integrated and the integrated signal charges the first capacitance, the charge of which increases with it and indicates the presence of a SECAM BG signal.

However, this only happens when the color burst signals of the reproduced Color-under color image signal the one described above, from image line to image line have changing frequency, which changes from line to line above the Frequency of the red color burst signal of a SECAM BG Color-under color image signal or a frequency below the frequency of the blue color burst signal of a reproduced SECAM BG Has color-under color image signal. Only in this case is the image line too Alternating inversion of the sign of the reproduced color image signal or its color burst signal a charge the first capacity. In all other color signal standards and this is also the case in their color-under color image signals alternate frequency position of the color synchronization signals is not provided. In these In the product, a signal with the same sign occurs in every image line. By inverting the sign from image line to image line are contained in the signal that is integrated, pulses from picture line to Image line change its sign. So there is a significant charge of Capacity no longer taking place. This shows the state of charge of the first capacitance clearly indicates whether the reproduced color under color image signal is one of the SECAM BG transmission standard is or not.

To detect a reproduced SECAM L color image signal in Color-under frequency position is the low-pass filtered signal, in which there is still no line by line alternating inversion was made, integrated and on a second Capacity coupled. The color burst signal of a SECAM L color image signal has in the color-under frequency range a frequency of 1.1 MHz. In the  Such a signal is therefore always a phase shift of product formation Subjected to 90 degrees so that in the product on the color burst signal declining impulses always have the same sign. Through the When this signal is integrated, the second capacitance is charged when a SECAM L standard signal is present. However, there is a signal from the SECAM BG standard before, impulses occur at the output of the mixer from picture line to picture line changing sign, which after integration does not have the second capacity charge significantly.

This allows the state of charge of the first and the second capacitance to be recognized the transmission standard of a reproduced, in color-under frequency position existing color image signal of the SECAM BG or SECAM L standard be used. This detection can, for example, take place directly in a VCR done; it reproduces the color image signals immediately evaluated without first having to convert to the standard frequencies.

The object stated above is therefore according to the invention for an arrangement solved that a multiplier, the first input of which is reproduced Color-under color image signal is supplied, and an oscillating circuit are provided on which the color image signal is coupled and which with a second Input of the multiplier is coupled that the resonant circuit Has natural resonance frequency, which is between the frequency of a Red color burst signal and that of a blue color burst signal one SECAM-BG signal in color-under frequency position is that the multiplier Series connection of a low-pass filter, a rectifier and inverter, the one Rectification and from picture line to picture line of the reproduced color image signal alternating inversion of the rectified signal, and a first Is connected downstream of the integrator, the output signal of a first capacitance is coupled, whose state of charge is a color signal of the SECAM BG transmission standard indicated, and that the low-pass filter is followed by a second integrator, the  Output signal is coupled to a second capacitor, the state of charge Color signal of the SECAM L transmission standard indexed.

On the input side, such an arrangement has a multiplier, the first of which Input the color-under color image signal in the original phase position becomes. The color-under color image signal is also applied to an oscillating circuit coupled, which in turn is coupled to a second input of the multiplier is. The resonant circuit has a natural resonance frequency which is between the Frequency of a red color burst signal and that of a blue color burst signal of a SECAM BG color image signal reproduced in color-under frequency position lies. The resonant circuit thus takes a phase shift in the supply to it Signal depends on whether this signal is a frequency above or below has its natural resonance frequency. For example, Playback of a SECAM BG signal present in the color-under frequency range whose color synchronizing signal changes from picture line to picture line Phase shift fed to the second input of the mixer. A reproduced SECAM L signal, however, experiences the same Phase shift of +90 degrees.

To recognize a signal of the SECAM BG transmission standard Multiplier a series connection of a low pass filter, a rectifier and Inverter and a first integrator connected. In the manner described above the integrator generates a signal coupled to a first capacitance whose State of charge the presence of a reproduced SECAM BG color image signal indicated.

To detect a reproduced color-under color image signal from SECAM L transmission standard is followed by a second integrator after the low-pass filter, whose output signal is coupled to a second capacitance.  

By the behavior of the coupled to the second input of the multiplier The resonant circuit or its natural resonance frequency ensures that the The second input of the multiplier is supplied with a color synchronizing signal if it is present of a signal of the SECAM BG standard alternating from picture line to picture line Undergoes phase shift. Color burst signals from image signals of others Transmission standards experience such an alternation from line to line Phase shift not. This behavior of the resonant circuit shows that Product in the manner described above either from image line to image line pulses alternating sign or the same sign. Hence we in above described way alternatively loaded the first or the second capacitance, so that can be recognized whether the reproduced color image signal in Color-under frequency position a signal of the SECAM BG or SECAM L transmission standard is.

A further embodiment of the arrangement according to the invention is through the Characterized according to claim 3. To increase the Detection reliability will be those that drop above the capacities Voltages using a comparator, each with a reference voltage compared. It is recognized whether those falling above the capacities Voltages are above or below the reference voltage. The Comparators deliver a corresponding output signal, which indicates the presence a color image signal of the SECAM L or SECAM BG standard. The comparators can further increase the detection reliability.

Another embodiment of the invention is in accordance with the features of Claim 4 provided. By blanking out the ones fed to the multiplier The multiplier only provides an output signal when it is in the multiplier supplied color image signals in color-under frequency position color synchronous signals are included. So the multiplier actually only delivers a product of Color synchronizing signals that can be evaluated immediately.  

A further embodiment of the invention according to claim 5 increases Recognition security again, since the presence of a SECAM BG signal second capacitance and, in the presence of a SECAM L signal, the first capacitance is discharged. This leads to the fact that the presence of a color image signal other transmission standard, the capacity is discharged immediately, so that not through Charging residues in the capacity a possibly wrong transmission standard by the Capacity is signaled.

A further embodiment of the invention is defined in that in claim 6 Characteristics marked. In many receivers or playback devices anyway integrated a PAL detection circuit. Delivers one PAL detection circuit is a signal that indicates the presence of a reproduced PAL signals signaled in the color-under frequency position, so the two capacities discharge the circuit arrangement according to the invention, since in this case a signal the SECAM BG or L standard cannot exist. Here too, the Unloading reaches the cargo remnants created by a previously recognized SECAM BG- or the SECAM L signal can be removed immediately.

An embodiment of the invention is shown in the drawing Arrangement explained in more detail. Show it:

Fig. 1 is a block diagram of an arrangement for detecting the SECAM L- or SECAM BG transmission standards,

FIG. 2 shows some signals of the arrangement according to FIG. 1 which are shown over time and which occur when a SECAM BG color image signal is present and

Some signals Fig. 3 shown over time as they occur in the circuit of Fig. 1 when there is a L-SECAM color image signal.

A signal Vin is fed in on the input side of the arrangement shown in FIG. 1 in the form of a block diagram. This signal is a color image signal reproduced by a recording medium and is in the color-under frequency position. Color image signals of all transmission standards are usually converted into such a frequency position before recording. The color image signals and the color synchronization signals contained in them are mixed down to a frequency position which is below the frequency position of the recorded brightness signal. Such a signal is therefore referred to as a color under signal.

The arrangement shown in FIG. 1 should already recognize in the color-under frequency position whether the reproduced color image signal is one of the SECAM BG or the SECAM L standard. Strictly speaking, the reproduced signals do not correspond to the SECAM BG or SECAM L transmission standard, but rather represent color under signals in which the color synchronization signals have been converted into the color under frequency position. Even in this frequency position, however, certain characteristics of the transmission standards are retained, so that it can be recognized whether the reproduced signal which is in the color-under frequency position is due to a signal of the SECAM BG or SECAM L standard.

The signal Vin is fed to a first input of a multiplier 2 . It is also coupled via a coupling capacitance 3 to a parallel resonant circuit 4 which has a capacitance, a resistor and an inductance. The parallel resonant circuit 4 is coupled to a second input 5 of the multiplier 2 . The multiplier 2 is also supplied with a blanking signal BK which is generated when a color synchronization signal occurs in the color-under color image signal Vin.

The multiplier 2 is followed by a low-pass filter 6 , which carries out low-pass filtering of the product supplied by the multiplier 2 .

To detect a signal of the SECAM BG standard, the low-pass filter 6 is followed by a rectifier and inverter 7 . The rectifier and inverter 7 first rectifies the signals supplied to it. The rectified signals are subsequently inverted alternately from picture line to picture line, ie the polarity of the rectified signals is changed in every second picture line. For this purpose, a signal fH / 2 is supplied to the rectifier and inverter 7 , which represents a corresponding clock signal as a function of the line frequency.

The rectifier and inverter 7 is followed by an integrator 8 , the output signal of which is coupled to a first capacitor 9 . The voltage dropping across the capacitance 9 is also fed to a comparator 10 which compares this voltage with a reference voltage Vref. The comparator 10 then supplies an output signal VsecBG.

In order to detect a color image signal in the color-under frequency position of the SECAM L transmission standard, the low-pass filter 6 is followed by an integrator 11 , the output signal of which is coupled to a second capacitance.

The voltage drop across the second capacitance 12 is further compared with a reference voltage Vref by means of a comparator 13 . The second comparator 13 supplies a signal VsecL on the output side.

The two capacitances 9 and 12 or their charge states signal the presence of a SECAM BG or a SECAM L color image signal in the color-under frequency position.

To increase the detection reliability, the capacitors 9 and 12 are discharged, if necessary, by means of switches 14 and 16 .

For this purpose, the first capacitance 9 is coupled via a resistor 15 to a switch 14 , which may discharge the capacitance. The switch 14 can either be activated if the comparator 13 supplies an output signal VsecL or if an external PAL detection circuit, not shown in the figure, detects the presence of a signal of the PAL standard. In these two cases, the charge of the capacitance 9 can be dissipated to ground by means of the switch 14 .

In a corresponding manner, the capacitance 12 can be discharged via a resistor 17 by means of the second switch 16 if the comparator 10 supplies an output signal VsecBG or if the external PAL detection circuit detects the presence of a signal of the PAL standard.

As a result, both capacitances 9 and 12 are discharged when neither a signal of the SECAM BG nor the SECAM L standard is reproduced, but one of the PAL standard was recognized. Furthermore, the capacitors are alternately discharged by means of the switches 14 and 16 , when a signal of the other transmission standard has been recognized. This removes charge residues from a previously recognized SECAM BG or SECAM L signal.

The mode of operation of the arrangement according to FIG. 1 is explained in more detail below with reference to FIGS. 2 and 3.

FIG. 2 shows some signals shown over time as they occur in the circuit arrangement according to FIG. 1 when the signal Vin is a signal of the SECAM BG standard that is present in the color-under frequency position.

The curve A in Fig. 2 shows this input signal. In a signal of the SECAM BG standard in color-under frequency position, the red or blue color synchronizing signals, which are identified in the figure with F0R 'or f0B', occur at frequencies of 654 kHz or 810 kHz. This signal is fed to the first input 1 of the multiplier 2 of the arrangement according to FIG. 1 in unchanged form. The signal is also coupled to the parallel resonant circuit 4 , which has a natural resonance frequency that lies between the frequencies 654 kHz and 810 kHz, preferably in the middle between these two frequencies. The SECAM BG signal present in the color-under frequency position and supplied to the second input 5 of the multiplier 2 thus experiences a phase shift of + or -90 degrees, depending on whether the frequency of the signal is above the natural resonance frequency of the resonant circuit 4 or below its frequency lies. In the multiplier 2 , blanking is carried out in such a way that the multiplier delivers output signals only during those times in which a color-synchronizing signal is present in the signal A or in the phase-shifted signal. As a result, only the color synchronization signals of the signals fed to the multiplier are evaluated.

After rectification by means of the rectifier 6 , the signal marked B in FIG. 2 occurs. As a result of the phase shift, described above, changing from picture line to picture line, which is generated by the parallel resonant circuit 4 , pulses of changing polarity occur at the output of the multiplier 2 and at the output of the low-pass filter 6 from picture line to picture line, which are attributable to the changing frequency of the color synchronizing signal.

The course of the signal C of the representation according to FIG. 2 shows the output signal of the rectifier and inverter 7 of the arrangement according to FIG. 1. The signal C shows that, apart from rectification, the signal was inverted during every other image line. The consequence of this is that the negative pulses occurring in signal B, which occur during every second image line, now have a positive sign. The signal C thus has only positive pulses which are integrated by means of the integrator 8 and are coupled to the capacitance 9 .

The signal D the representation of FIG. 2 shows the voltage across the capacitor 9. If a signal of the SECAM BG standard is present in the color-under frequency position, the capacitance 9 is charged by the pulses of the signal C that have been integrated. However, this loading of the capacitance 9 takes place only if a corresponding phase shift occurs in the output signal of the multiplier 2 as a result of the changing frequencies of the color synchronization signals of a color-under signal of a signal of the SECAM BG standard, and therefore corresponding alternating signs occur at the output of the multiplier 2 . These alternating signs are in fact compensated for by the line-alternating inversion of the rectifier and inverter 7 , so that its output signal, in the presence of a signal of the SECAM BG standard, in turn supplies only positive impulses. If it is, for example, a signal of the SECAM L standard, whose color synchronizing signal has a constant frequency of 1.1 MHz in color-under frequency position in each picture line, the output signal of the multiplier has only positive impulses, which are generated by the rectifier and Inverters 7 are inverted alternately from image line to image line, so that positive and negative pulses would alternately occur in the signal C, which after integration have not significantly charged the capacitance 9 . A charge of the capacitance 9 thus signals the presence of a SECAM BG color image signal. The reliability of detection can be increased by the comparator 10 as shown in FIG. 1 by comparing the state of charge of the capacitor 9 with a reference voltage Vref. The comparator 10 then supplies a signal VsecBG, which indicates the presence of a color image signal of the SECAM BG standard, which is reproduced in the color-under frequency position.

In Fig. 3, in turn, some of the signals are shown over the time from which the signal A, in turn, the input signal of the multiplier 2 is of the first input 1 of the circuit arrangement according to FIG. 1 supplied signal Vin. In the example according to FIG. 3, it is assumed that this signal is a signal of the SECAM L standard that is present in the color-under frequency position. Its color synchronizing signal has a constant frequency of 1.1 MHz in the color-under frequency position.

Since the parallel resonant circuit 4 of the arrangement according to F%. 1 has a natural frequency that is between 654 kHz and 810 kHz, the signal A is fed with a constant phase shift of +90 degrees to the second input 5 of the multiplier 2 , so that it corresponds to the curve representation B according to FIG. 3 during the time, in which color burst signals appear in the signals, only provides positive impulses.

These are fed to the second integrator 11 after low-pass filtering in the circuit arrangement according to FIG. 1, the output signal of which is coupled to the second capacitor 12 , the state of charge of which is shown in the curve E in FIG. 3.

In the presence of a color image frequency signal reproduced in the color-under frequency position of the SECAM L standard, for the reasons explained above, only positive pulses occur at the output of the multiplier 2 , which can be integrated directly after low-pass filtering and charge the second capacitance 12 , the charge state of which thus Presence of a reproduced signal of the SECAM L standard indexed.

If, on the other hand, a signal of the SECAM BG standard is reproduced, for example, the signal shown in FIG. 2 appears at the output of the low-pass filter 6 and has a sign that changes from picture line to picture line. The integration by means of the integrator 11 does not lead to any significant charging of the capacitance 12 , so that the charge of the capacitance 12 remains low when such a signal is present and no signal of the SECAM L standard is recognized.

To increase the detection of a signal of the SECAM L standard, the second comparator 13 compares the charge state of the second capacitance 12 with a reference signal Vref and supplies a corresponding output signal VsecL, which indicates the presence of a signal of the SECAM L standard.

The arrangement shown in FIG. 1 thus signals in a reliable manner by means of the signals VsecBG or VsecL whether the reproduced color image signal in the color-under frequency position is one of the SECAM BG or the SECAM L standard.

Claims (6)

1. A method for recognizing the SECAM L and SECAM BG transmission standards when reproducing a color image signal recorded on a recording medium using the color-under method, characterized in that the color synchronization signal of a reproduced color-under color image signal is multiplied by itself, wherein one of the two color synchronizing signals is subjected to a phase shift of +90 degrees if it has a frequency which is above the frequency of a red color synchronizing signal of a SECAM-BG signal in the color-under frequency position, or is subjected to a phase shift of -90 degrees if it has a frequency below the frequency of a blue color burst signal of a SECAM-BG signal in the color-under frequency position,
that the product is subjected to low-pass filtering, rectification, an image line alternating inversion and subsequent integration,
that the integrated signal is coupled to a first capacitance whose state of charge indicates a color signal of the SECAM BG transmission standard,
and that the low-pass filtered signal is integrated and the integrated signal is coupled to a second capacitance, the charge status of which indicates a color signal of the SECAM L transmission standard. 2. Arrangement for recognizing the SECAM L and SECAM BG transmission standards when playing a color image signal recorded on a recording medium using the color-under method, characterized in that a multiplier ( 2 ), the first input ( 1 ) of which is a reproduced color -Under color image signal is supplied, and an oscillating circuit ( 4 ) are provided, to which the color image signal is coupled and which is coupled to a second input ( 5 ) of the multiplier ( 2 ),
that the resonant circuit ( 4 ) has an intrinsic resonance frequency which lies between the frequency of a red color synchronizing signal and that of a blue color synchronizing signal of a SECAM-BG signal in the color-under frequency position,
that the multiplier ( 2 ) is followed by a series connection of a low-pass filter ( 6 ), a rectifier and inverter ( 7 ), which carries out rectification and inversion of the rectified signal which changes from picture line to picture line of the reproduced color image signal, and a first integrator ( 8 ), whose output signal is coupled to a first capacitance ( 9 ), the charge status of which indicates a color signal of the SECAM BG transmission standard,
and that the low-pass filter ( 6 ) is followed by a second integrator ( 11 ), the output signal of which is coupled to a second capacitance ( 12 ) whose charge state indicates a color signal of the SECAM L transmission standard. 3. Arrangement according to claim 2, characterized in that the voltages falling across the capacitances ( 9 ; 12 ) are each compared by means of a comparator ( 10 ; 13 ) with a reference voltage and that the comparators ( 10 ; 13 ) each deliver an output signal , which signals a color image signal of the SECAM L or SECAM BG standard. 4. Arrangement according to claim 2, characterized in that the multiplier ( 2 ) is supplied with a blanking signal which controls the multiplier ( 2 ) so that it only delivers an output signal during those times in which a color synchronization signal is included in the color image signals supplied to it is. 5. Arrangement according to claim 2, characterized in that the first capacitance ( 9 ) is discharged when a color image signal of the SECAM L standard is detected, and in that the second capacitance ( 13 ) is discharged when a color image signal of the SECAM BG standard is recognized. 6. Arrangement according to claim 2, characterized in that both capacitances ( 9 , 13 ) are discharged by means of switches ( 14 , 16 ) when a PAL detection circuit signals that the reproduced color image signal is one of the PAL standard .