DE2661021C3 - - Google Patents

Description

The invention is based on a method according to the Genus of the main claim.

It is already a system for storing color image signals known (DT-AS 20 56 684), in which the color information during the back porch of the television signal is recorded, wherein it is assumed that the return time will be extended becomes what will shorten the usable Duration of the lines leads. With this known system it is assumed that the compression factor for the color information is about 5.

Furthermore, a similar system has become known (GB-PS 13 73 943), in which the line duration that can be used for the luminance information is also shortened, but in which the color difference signals (BY) and (RY) are transmitted alternately line by line. With this system, chromaticity errors during reproduction can arise from amplitude errors during transmission or recording. Finally, a method for the digital transmission of color television signals is known (Iinuma, Iÿima, Ishiguro, Kaneko and Shigaki: Interframe Coding for 4-MHz Color Television Signals, IEEE Transactions on Communications, p. 1461, Vol. Com-23, No. 12, December 1975), in which the color difference signals are also transmitted line by line compressed in virtually the entire blanking intervals. For the transmission of the synchronizing signal, a short pulse (6 sampling periods long) is provided at the beginning of each color difference signal, which may be sufficient for the analog transmission for the digital transmission, for which a much larger bandwidth than for the analog transmission must be provided Transmission but is too short. Furthermore, the transmission of a blanking value is not necessary in such a digital transmission, so that no precautions have been taken in this known system.

The invention has for its object a method to create at which the color information time-compressed line sequentially during the Hori zonal blanking and / or recorded is and the transmission or recording of Color information regarding the resolution and less color distortion is improved under Maintaining a broadband luminance signal.  

Advantages of the invention

The inventive method with the characteristic Features of claim 1 has the advantage that arises during the transmission or recording Amplitude errors can at best be seen as color saturation errors however not noticeable as a color error do.

The procedure with the characteristic features of the Claim 2 enables sufficient synchronization. In addition, with the help of this synchronizing pulse on during playback or at Reception of the transmission signals of necessary switches be synchronized for the color difference signals.

By the measures listed in the subclaims are advantageous further developments and improvements the procedure specified in the main claim possible.

Finally, it should be mentioned that when using malfunctions of the method according to the invention, which are known to be due to phase modulation the used in the color television methods NTSC and PAL Subcarriers arise, do not occur and that, on the other hand, limits on the bandwidth of the used Transmission channel or recording device equally on the luminance information and affect the brightness information. This ensures even with stronger band limits still relatively high color image quality.

drawing

The procedure and instructions through implementation of the process are described in the description below explained in more detail and shown in the figures. It shows

Fig. 1 is a voltage-time diagram of a signal according to the inventive method,

Fig. 2 shows schematically a block diagram of a coder for converting a three-channel signal present in a signal according to the inventive method,

Fig. 3 shows a circuit detail of the coder,

Fig. 4 schematically shows color difference signals during several lines of a television picture to explain the circuit of Fig. 3 and

Fig. 5 schematically shows a block diagram of a decoder.

Description of the invention

The voltage-time diagram according to FIG. 1 is based on a color bar test image. The periods between t ₀ and t ₂ or t ₃ and t ₅ correspond approximately to the blanking interval of conventional television signals. During the time from t ₂ to t ₃, the luminance signal is transmitted as in the conventional television method. This ensures that when the method according to the invention is used, the luminance signal can be transmitted or recorded without complex coding or decoding which may impair the quality.

As can be seen from Fig. 1, the color information is transmitted during the vast majority of the blanking interval by conventional methods, namely from t ₁ to t ₂ the color difference signal BY and from t ₄ to t ₅ the color difference signal RY .

As for the transmission of the color difference signals as large a part of the output interval as possible remains for the sync pulse as well as for the blanking value only a short time remaining.

It is therefore proposed to transmit the synchronizing pulse during one line and the blanking value in the following line. In Fig. 1, a synchronizing pulse is therefore shown between t ₀ and t ₁, the amplitude of which lies outside the amplitude range of the image content, so that the synchronizing pulse can be separated by the known circuit means.

The blanking value is transmitted in the following line from t ₃ to t ₄. When using color difference signals, the blanking value advantageously corresponds to the achromatic value, which is approximately 50% of the amplitude provided for the image content.

Fig. 2 shows a block diagram of a coder for deriving signals according to Fig. 1. The inputs 1 , 2 and 3 of a conventional matrix circuit 4 are supplied with color value signals R , G and B. The luminance signal Y and the color difference signals RY and BY are then available at the outputs 5 , 6 and 7 of the matrix circuit 4 .

The color difference signals are fed to an electronic switch 8 , which is controlled with square-wave pulses at half the line frequency, so that RY is passed on during one line and during the subsequent BY . The pulses required to control the switch are taken from a pulse generator 9 . The pulses H , A , V and S common in television technology are taken from this. These pulses are generated by circuits customary in television technology and need not be explained in more detail in connection with the present invention.

The pulse fed to the changeover switch 8 with half the line frequency is shown in line b) of FIG. 1. The color difference signals are present in line-sequential form at the output of the switch 8 . They are time compressed in the compression circuit 10 . The compression circuit 10 can be constructed with suitable memory elements such as, for example, bucket chain circuits, charge-coupled memories and series-analog memories.

Since such circuits store instantaneous values of the signals, it is necessary to take the sampling theorem into account when controlling the compression circuit. This means that the writing and reading out must be carried out at frequencies that are at least twice as high as the highest frequency contained in the respective signal. This is guaranteed when writing at a clock frequency of, for example, 2.5 MHz, so that the frequency when reading out is then 12.5 MHz. To avoid interference, a low-pass filter 11 with a cut-off frequency of 1 MHz is provided before the compression circuit and 5 MHz after the compression circuit.

The pulses required to control the compression circuit are processed in the clock generation circuit 13 . The readout clock frequency is generated in a voltage-controlled oscillator 14 , the frequency of which is divided by five, so that the write-in clock is available at the output of the frequency divider 15 . In a further frequency divider 16 , line-frequency pulses are generated, the phase position of which is compared in the phase comparison circuit 17 with the horizontal frequency pulses H obtained from the signal S in the circuit 9 . The output voltage of the phase comparison circuit is then fed to the oscillator 14 for frequency readjustment. The clock pulses are T _in and T _out constantly at the corresponding inputs of the compression circuit. The write-in or read-out process is triggered by start pulses which are generated by a corresponding link between the clock pulses and horizontal-frequency pulses. The start pulse ST are shown in the rows c) and d) of FIG. 1 _and ST _from.

The compressed color difference signals are fed to a clamping stage 18 . The clamping takes place during the periods t ₀ to t ₁ and t ₃ to t ₄. The required for controlling the clamping step impulses H _c are produced by linking the H pulses with pulses of the ₁ Einschreibtaktes T _{is a} pulse shaper in the nineteenth

The clamping potential is supplied at 20 and is preferably U _c = 50% of the amplitude range of the luminance signal.

To avoid interference, it has proven to be advantageous to synchronize the switching phase of the switch 8 with the vertical pulse V. It then follows that the same color difference signals are transmitted in successive frames in the same line pairs. For this purpose, the V pulse is linked in circuit 21 with the H 1 pulse. This can be done with the circuit shown in Fig. 3, namely the so-called trigger input of a JK flip-flop of the H ₁ pulse and the reset input R of the V pulse. The square-wave signal shown in line b) of FIG. 1 with half the line frequency is then available at output Q.

FIG. 4 schematically shows some lines 316, 317 etc. of a first field and some lines 4, 5, 6 of a second field. With the help of the synchronization of the changeover switch 8 described above it is achieved that the assignment of the color difference signals shown in FIG. 4 is repeated in the same way from frame to frame.

Since the synchronization pulse is to be transmitted only in every second line, the pulse h _c shown in line e) of FIG. 1 is linked to the output voltage of the circuit 21 shown in line b) , so that the pulse S ' shown in line f) arises. For this purpose, a NAND circuit 22 is provided. In addition, it has proven to be advantageous to transmit the normal synchronization signal during the vertical frequency blanking interval. Therefore, the pulse S 'is linked with the logic circuits 23 , 24 , 25 and 26 with the pulses V and S and added to the signal to be transmitted or recorded using the addition circuit 27 .

The electronic switch 28 is controlled by an A pulse, which corresponds to the usual in television technology blanking pulse so that the matrix 4 with the addition circuit 27 and during the blanking interval the clamping stage 18 with the addition circuit 27 is connected during the usual trace time the output 5 is.

The signals shown in line a) of FIG. 1 are then available at the output 29 of the encoder.

Fig. 5 shows a decoder for decoding the time-sequentially encoded television signals. The signals transmitted or reproduced by a recording medium are fed to the input 31 . Via a clamping circuit 32 , they arrive at the changeover switch 33 . The clamping circuit 32 serves to restore the DC voltage level and is driven with the pulse H ' _c shown in line h) of FIG. 1.

The switch 33 is controlled with the pulse A in such a way that it is in the drawn position during the run, so that the luminance signal is passed to the input 34 of the dematrix 35 . During the blanking interval, switch 33 is in the up position. The circuit 36 is used for decompression and for storing the color difference signals over one line each. Like the circuit 10 in the coder, it can be constructed with the aid of bucket chain circuits or similar memory elements. A circuit which is particularly favorable for the present purposes is described in the patent application P 26 29 707 which was filed at the same time. Such a circuit has three inputs, of which the input 37 is provided for the sequential sequence of the color difference signals and the inputs 38 and 39 for each of the difference signals RY and BY . The electronic changeover switch 40 , which is driven by an H / 2 pulse, as shown in line b) of FIG. 1, is used to distribute the color difference signals to the inputs 38 and 39 .

The decompressed color difference signals are available at the outputs 41 , 42 and 43 of the circuit 36 , in such a way that the color difference signals occur at the output 42 in line- sequential fashion and the color difference signal is present at the inputs 41 and 43 , which is not present in the respective line at the output 42 occurs.

In order to supply the color difference signals to the inputs 44 and 45 of the dematrix 35 simultaneously, the electronic changeover switches 46 and 47 are provided, which in turn are controlled with H / 2 pulses.

Low-pass filters 48 and 49 are also provided, which suppress the higher-frequency interference caused by the sampling of the instantaneous values in the circuit 36 .

The color value signals R , G and B are then available at the outputs 51 , 52 and 53 of the dematrix 35 . The clock is generated in the decoder in the same way as with the coder. In circuit 13 , which corresponds to the corresponding circuit in the coder, the individual modules are therefore provided with the same reference numerals as in FIG. 2. When activating the decompression circuit 36 , however, the read-in and read-out cycles are interchanged with respect to FIG. 2. In addition, the output pulses h _{c are} linked to the H / 2 pulses such that not as in the circuit of FIG. 2, the pulse S ' shown in line f) of FIG. 1, but the pulse H shown in line h) _c arises. Gates 56 and 57 serve this purpose.

By the same structure of the circuit for clock generation for the decoder and the coder, this results Advantage that compression may result temporal non-linearities in decompression be balanced again.

The circuit 58 for pulse generation is also constructed similarly to the corresponding circuit of the encoder. However, in contrast to the circuit of the encoder, it is not synchronized with the usual synchronizing signal, but with the signal S ' contained in the transmitting signal during every second line. A flywheel circuit known per se is used for this purpose. It has been found that the usual phase comparison circuits may also work satisfactorily with minor changes if a synchronization pulse occurs only in every second line. The pulse S ' is separated from the transmitted time-division multiplex signal using a conventional amplitude sieve together with the usual synchronizing signal occurring in the vertical frequency blanking interval.

Finally, a standardized synchronization signal S is obtained in the circuit 58 by means customary in television technology, which is available at the output 59 together with the color value signals.

The outputs 51 , 52 , 53 and 59 can, for example, be connected to a conventional encoder for generating an NTSC, PAL or SECAM color television signal.

In the clamping stage 32 , the incoming signals are clamped in such a way that the level occurring in the period t ₃ to t ₄ ( Fig. 1) corresponds to the ground potential. After the switch 33 , this level results in the luminance signal during the entire blanking interval. However, in order to obtain a blanking value in accordance with the standard in the case of black in the luminance signal, the changeover switch 50 is provided, which assumes the lower position during the blanking interval. The corresponding input of a voltage -U _c is supplied, which - apart from the sign - the voltage U _c corresponding to that fed 18 (Fig. 2) of the clamping circuit.

As already mentioned, temporal non-linearities can arise during the compression, namely in that the controllable oscillator 14 changes its frequency during one line at a time. As also already mentioned, it is therefore advisable to design the clock generation circuits for compression and decompression in the same way. If this is possible for spatial reasons, a circuit for clock generation can also be advantageously provided, which optionally outputs clock pulses for compression and decompression, which is possible in particular when using the method according to the invention when recording and reproducing color television signals.

In order to make the best possible use of the available amplitude range during the transmission of the color difference signals, it is advisable to choose the coefficients of matrix 4 ( FIG. 2) in such a way that the amplitudes of the color difference signals for standard color bars - i.e. the maximum amplitudes - have the same values .

Claims (9)

1. A method for transmission and / or recording of color television signals in analog form, the luminance information during approximately 80% of the line duration and the color signals being time-compressed line sequentially transmitted during the horizontal blanking interval of a standardized television signal, characterized in that the color signals as color difference signals during the Most of the remaining 20% of the line duration are transmitted or recorded and that a blanking value is transmitted during a time which is small compared to the time available for the transmission of the color signals, which is at the achromatic value of the color signals and at about 50% of the intended Amplitude range is. 2. The method according to claim 1, characterized in that that a blanking value is only in every second line and only in the other lines a sync pulse is transmitted.   3. The method according to claim 2, characterized in that the sync pulse a given Color difference signal is assigned. 4. The method according to claim 1, characterized characterized in that during the vertical blanking interval a synchronization signal according to a common television standard is transmitted. 5. The method according to claim 1, characterized in that the color information is about the factor 5 is time compressed. 6. The method according to claim 1, characterized in that the amplitudes of the color difference signals have the same values for standard color bars. 7. Circuit arrangement for performing the method according to claim 1, characterized in that for compression and decompression signals are written into and read from memory with the aid of clock pulses, that a controllable oscillator ( 14 ) whose frequency is a multiple of the line frequency for clock generation, and frequency dividers (15, 16) are provided whose output signals are supplied to a phase comparison circuit (17), that the phase comparison circuit are supplied (17) further horizontal rate pulses and that the output voltage of the phase comparison voltage (17) to the controllable oscillator (14) in terms of frequency - and phase control is supplied. 8. Circuit arrangement according to claim 7, characterized characterized in that the circuits for clock generation in compression and decompression are constructed in the same way. 9. Circuit arrangement according to claim 7, characterized characterized in that a circuit for clock generation is provided, the optional clock pulses delivers for compression or decompression.