DE3841073A1 - Colour television transmission system - Google Patents

Abstract

In a colour television transmission system according to the NTSC standard, so-called Fukinuki holes in the spectrum and an overscan area of the tube are utilised for compatibly transmitting edge information of a 16 : 9 picture format. For the transmission and for the reception of standardised television signals having a picture format of 4 : 3 for reception on a standard receiver and additional information items for a picture format of 16 : 9 for reception on a receiving device decoding this picture format, the additional information in a PAL signal is modulated on the colour information (U, V) existing in the PAL signal, in such a manner that spectral spaces of the colour information (U, V) are occupied twice. For PAL receiving sets having a standard aspect ratio and a wider aspect ratio. <IMAGE>

Description

The invention relates to a color television transmission system.

The introduction of an HDTV service will change alongside one the number of lines may also have a different image format, which is more adapted to the movie. While the spec is currently an open format for HDTV is an image format with an aspect ratio of 16: 9 (compared to today's gen 4: 3 format) already generally accepted.

In the United States, works have become known which aim to transmit such a 16: 9 image format compatible with the NTSC standard. For example, an article by H. Wekenbrock, W. Wedam: "ACTV: Advanced Compatible Television - Proposal for a new, compatible widescreen television standard for the USA ", which reflects the status of this work.

For a PAL system, there are basically similar possibilities as with ACTV to modulate the 16: 9 edge information onto another subcarrier and to transmit it in a way that is compatible with 4: 3 information. However, this subcarrier must then have a different spectral position than in an NTSC system, since "free spaces" in the PAL spectrum (so-called Fukinuki holes, which have to be generated by appropriate filtering) are located precisely at the locations in the NTSC System for color transfer ( I , Q ).

Tests have shown that the additional information in their Amplitude must be reduced by approximately 20dB to an almost interference-free compatible reception on one To ensure standard receivers. In addition, at ACTV the high energy lower frequencies of the  Additional information in the overscan area of the line above will wear. The overscan area is the duration of one Line through the scanning grid and its tolerances is not shown. This range can vary, so that on standard receivers in the lateral edge area transmitted additional information may be visible.

The invention has for its object a compatible Specify transmission system for a PAL signal, which at Standard receivers an image format of 4: 3 and with improvements ten receivers delivers an image format of 16: 9.

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

On the transmitter side, the additional information representing the larger picture format of 16: 9 is modulated onto the color information U , V transmitted in the PAL signal. A type of modulation is selected by which the spectral spaces of the color information U , V are occupied twice. This can e.g. B. by quadrature modulation. In a standard receiver that decodes the color information U , V , the additional information is thus suppressed due to the lack of a corresponding decoder. An improved receiver with an aspect ratio of 16: 9, on the other hand, contains appropriate decoders which, together with the decoders, provide an aspect ratio of 16: 9 for the standard signal.

An embodiment is shown below with reference to the drawing explained in detail.

Show it:

Fig. 1 spectrum of an NTSC signal in the plane of vertical spatial frequencies and temporal frequencies (based on active line numbers)

Fig. 2 spectrum of a PAL signal in the plane of vertical spatial frequencies and temporal frequencies (based on active line numbers)

Fig. 3 Wide Screen PAL coder

Fig. 4 representation of the aspect ratios 4: 3 and 16: 9

Fig. 5 luminance resolution of the 16: 9 edge information

Fig. 6 time division (Timeplex) packets for a first embodiment

Fig. 7 time division packets for a second embodiment

Fig. 8 filter device 11 for the second embodiment

Fig. 9 Wide screen PAL decoder

Fig. 10 arrangement for joining luminance components of FIG. 5.

In Figs. 1 and 2, the spectral positions of luminance and chrominance for an NTSC and a PAL signal in the fy-ft plane reflect.

From Figs. 1 and 2 is further seen that a fundamental difference in the color transfer in both NTSC and PAL is. Due to the line-alternating switching phase of the V signal in the PAL system, the chrominance signals U , V of the PAL system do not occupy the same places in the spectrum as is the case with the I , Q signals of the NTSC system. According to the invention, these spectral spaces are occupied twice in the PAL system by modulating an additional signal in quadrature onto the color carrier.

The color television transmission system, in the following wide screen Called PAL, it enables coding and PAL-compatible Transmission of 16: 9 picture signals. The additional The color carrier receives information about the 16: 9 edge signals  modulated in quadrature. Such a system offers following advantages:

• - Good compatibility with the conventional PAL receiver
  • (i) the conventional PAL receiver supports the suppression of cross-luminance interference by notch filtering in the luminance path.
  • (ii) in the case of synchronous color demodulation, the quadrature component additionally modulated onto the color carrier is not decoded.
• - Direct recordability of the Wide Screen PAL signal in PAL studio.
• - Easy recovery of the wide screen signals because of the color burst is guaranteed sufficient stability.

Fig. 3 shows a Wide Screen PAL coder for coding of the wide format of a PAL signal. Signals with a 16: 9 aspect ratio can be considered as source signals. These signals can come from a progressive scan or an interlaced scan (e.g. 1250/50/1: 1, 1250/50/2: 1, 625/50/1: 1, 625/50/2: 1 or 529/60 (2: 1) (PAL-M)). For source signals other than the transmission standard, filtering and line number transcoding must ensure that a signal corresponding to the transmission standard is available for processing. The information to be processed for the color separations R , G , B with an aspect ratio of 16: 9 on a 625 line basis is first converted in a matrix 1 into the luminance component Y and the two color components U and V. These 16: 9 component signals are then split in a separator circuit 2 into the signals of the 4: 3 center information and into the 16: 9 edge information, as shown in FIG. 4. Since the 4: 3 center information only makes up 75% of the 52 µs of an active line, these signals have to be expanded by 25% in time in order to generate a signal that is compatible with the standard receiver and has the correct geometry. This is effected by an expansion circuit 3 . A conventional notch filter 4 can then be inserted into the luminance path Y to avoid cross-color interference. The chrominance signals U , V are pre-filtered in a low-pass filter 5 for horizontal frequencies fx , for example to 1.3 MHz (-3 dB) (according to CCIR recommendations). A vertical low-pass filtering 6 of the vertical frequencies fy is then carried out, which limits the vertical resolution of the chrominance signals to 78 cycles / ph (vibrations / image height). As a result, the vertical color resolution is the same as for MAC signals. The system-theoretical necessity of this vertical pre-filtering can be seen immediately from FIG. 2, since then a vertical overlap - vertical alias - is avoided even with moving images, expansion of the spectral components in the ft direction. The chrominance signals pre-filtered in this way are then fed to a conventional PAL modulator 7 . The output signals of this PAL modulator 7 are the chrominance signals UF , VF which are quadrature-modulated with the PAL color carrier and which, together with the Y signal adapted in time in a runtime adaptation 8 and a standard synchronization signal, for example, form a conventional CVBS signal. The merging of these signals is made in a summation circuit 9 before. The PAL modulator uses - as usual - a 0-degree phase position of the color carrier for modulating the U-component, which is referred to below as Fu . Furthermore, the quadrature component Fv with 90-degree phase position, which is switched to +/- 90-degree phase position with the PAL switching phase. Both color carriers Fu , Fv are led out of the PAL modulator 7 and are available for processing the wide screen PAL signals.

The 16: 9 margin information takes up only 25% of the total line duration of 52 µs. The luminance signal Y is first supplied to an expansion circuit 10 and expanded in time by a factor of 4. The signal then arrives at a filter device 11 , which allows the components Y 1 and Y 2 to be generated, as shown in FIG. 5 for the non-time-expanded Y baseband signal. In a first embodiment, the filter device 11 generates the signal Y 2 , which was limited to 78 cycles / ph for vertical frequencies and horizontally occupies a bandwidth of 1 MHz (baseband 4 MHz, FIG. 5). After a runtime adjustment 12 , the signal arrives at a time division multiplexing device 14 , e.g. B. a time plexer, where together with the chrominance information packets of chrominance and luminance information are formed in time division.

The chrominance signals of the 16: 9 edge information are expanded in a compressor / expander 14 by a factor of 2 and then pre-filtered in a low-pass filter 15 to, for example, 500 kHz base bandwidth (corresponding to 250 kHz after expansion). The chrominance signals U , V then pass through a vertical filter 16 , which limits the vertical resolution to 78 cycles / ph. The time plexer 13 now selects the chrominance signals U , V and the luminance signals Y 2 signals in the manner shown in FIG. 6. The chrominance signals U , V each occupy 50% of the line time, the luminance signals Y 100% of the line time. The luminance information Y 2 is now supplied to a linear modulator 17 which, on the other hand, receives the color carrier Fu phase-rotated by 90 degrees in a phase shifter 18 as the modulation frequency. The chrominance information U , V is fed to a further linear modulator 19 , which now works with the ink carrier component Fv , which is phase-rotated by 90 degrees by a phase shifter 20 . The color carrier-frequency signals are then fed to attenuators 21 , 22 , where the amplitudes can be reduced by a factor a <1 in order to achieve better compatibility with the standard PAL receiver. The signals then arrive at the summation circuit 9 and are combined with the output signals of the standard PAL coding to form a compatible CVBS signal.

In a second embodiment, the vertical luminance resolution of the edge areas is increased. The required components Y 2 , Y 1 ', U and V are combined in the time plexer 13 in the manner shown in Fig. 7 into packets. The luminance component Y 2 takes up the full running time of a line, while the color components U , V each require 6.5 μs and the luminance component Y 1 39 μs. The broadband luminance component Y 2 is in turn modulated onto the Fu carrier. The filter device 11 now produces the components Y 1 and Y 2 in Fig. 5. A complementary vertical filter 11a in Fig. 8 provides a portion Y 2 with a vertical resolution of 0-78 cycl./ph and a portion Y having a resolution 1 from 78-156 cycl./ph. The luminance component Y 2 is in a horizontal filter 11 b to 4 MHz baseband bandwidth (1 MHz time expanded) limited. The luminance component Y 1 is vertically shifted by 78 cycl./ph by a converter 11 c , so that the position of the vertical frequencies now extends from 0-78 cycl./ph. After a horizontal filtering 11 d , the signal Y 1 'results with a base bandwidth of 3 MHz (0.75 MHz time-expanded). The chrominance information U , V of the 16: 9 edge signals take up a total of 13 µs in the active line. These signals are time-compressed by a compressor / expander 14 by a factor of 2 and then supplied to the low-pass filter 15 so that the base band to 500 kHz horizontal resolution is limited (1 MHz after compression). The vertical filter 16 then follows. The information packets according to FIG. 7 are generated in the time plexer 13 ( U / V , Y 1 '). These packages are modulated onto the Fv color support.

Fig. 9 shows a wide screen PAL decoder.

The CVBS signal is first fed to a conventional PAL demodulator 23 , which supplies the component signals Y , U , V of the center information in 4: 3 format. The chrominance signals U , V then pass through a vertical filter 34 and are low-pass filtered to 0-78 cycl./ph. A runtime adaptation 24 adjusts the Y, U , V signals to the 16: 9 edge information signals. Furthermore, the CVBS signal passes through a bandpass 25 , which has a minimum bandwidth of 2 MHz and whose center frequency is at the color carrier frequency. A clock generation 26 obtains from the signal contained in the composite color burst back the color carrier Fu and Fv, then the 90-degree phase shifters are supplied to 27 and 28th The clock generation also receives the non-bandpass filtered FBAS signal for generating a line-synchronous control signal S. The phase-shifted color carrier signals feed modulators 29 and 30 , which on the other hand receive the bandpass filtered FBAS signal. The demodulated component signals then experience an increase with the factor a -1 in accordance with the attenuation on the transmitter side in the amplifiers 31 , 32 . The amplifiers are followed by vertical filtering 33 , which limits the signals to 0-78 cycl./ph. The signals arrive at a demultiplexer 35 and are separated according to luminance and chrominance signals. A compressor / expander 36 compresses the chrominance signals for the first embodiment by a factor of 2 for the duration of the edge information, while the luminance signal is compressed by a factor of 4. The signals are then available for reading out in a memory device 37 for the duration of one line. A selector 38 is controlled via the control signal S and switches the Y , U , V signals through in a chronological sequence of edge information and middle information to a dematrix 39 which matrices onto the R , G , B color separations.

In the second embodiment, the luminance information consists of the components Y 1 'and Y 2 . FIG. 10 shows an arrangement for assembling luminance components according to FIG. 5. The demultiplexer 35 on the receiver side supplies both Y component signals. The Y 1 'component is expanded in an expansion circuit 40 to the active line length of 52 microseconds and added after conversion to the vertical position of 78-156 cycl./ph by means of a converter 41 in an addition circuit 42 to the Y 2 component. The luminance resolution according to FIG. 5 then results . The chrominance components U , V , which each only occupy 6.5 μs, are expanded in the compressor / expander 36 by a factor of 2 to the duration of the marginal information. The further processing of the Y , U , V signals by the circuit parts 37-39 takes place as described in the first embodiment.

Claims (1)

Color television transmission system for the transmission and reception of standardized television signals with an aspect ratio of 4: 3 for reception with a standard receiver and additional information for an aspect ratio of 16: 9 for reception with this aspect ratio decode the receiving device, characterized in that the standardized television signal is a PAL signal and that the additional information is modulated on the presence in the PAL signal color information (U, V) such that Spektralräume the color information (U, V) are doubly occupied.