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Description  |
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BACKGROUND OF THE INVENTION
The present invention relates to a circuit for playing back three-line
sequential color television signals, particularly for use in a video disc
player.
It is already known in the art to record a color television signal on a
recording device having a narrow bandwidth, typically about 3 MHz, by
recording the three color component signals representing the primary
colors in line-by-line alternance and, during playback, to make signals
representing the three color components simultaneously available by
employing a series connection of two line delay lines, as disclosed in
German Pat. No. 1,261,876 and corresponding U.S. Pat. No. 3,560,635,
issued to Walter Bruch.
In this connection, it is also known to effect this sequential recording of
the primary color signals only in the lower frequency band of about 0-0.5
MHz and to record during each picture line period a luminance signal in
the upper frequency band of about 0.5-3 MHz. During playback, the signals
in these two frequency bands coming from the recording device are first
separated by a frequency filter and directed into two respective channels.
The first channel permits only signal components in the lower frequency
range to pass and processes the sequential color signals. The second
channel permits only the signal components in the upper frequency band to
pass, i.e. it furnishes the high frequencies of the luminance signal which
are subsequently recombined with the processed signals in the lower
frequency band.
In such a circuit, the signal components in the lower frequency band always
pass only through the first channel. Thus all interferences and errors
occurring in the first channel, e.g. distortions from modulators, delay
lines and filters, become fully effective even in the case of a monochrome
picture signal.
It is known to reduce these errors, as disclosed in German Pat. No.
2,207,021 and corresponding U.S. Pat. No. 3,808,359 issued to Werner
Scholz, by transmitting signal components in the first frequency band also
in the second channel and adding a difference signal in this channel,
which difference signal is obtained by a special matrixing of the signals
from the first channel. Preferably, the signals are combined at the
outputs of a series arrangement of delay lines, each effecting a delay of
one horizontal scanning line period, in a certain amplitude ratio to form
the difference signal.
A playback circuit for such three-line sequential color television signals
is also disclosed in German Offenlegungsschrift [Laid Open Application]
No. 24 46 376, in which a third delay line having the same delay period is
disposed in series with the series circuit of the two above-mentioned
delay lines. The difference signal is then formed by utilizing the input
signal to the series circuit and the signals at the outputs of the three
delay lines.
This playback circuit is particularly suitable for the playback of a signal
which is subject to predistortion during recording. This predistortion,
which is also described in German Offenlegungsschrift No. 24 46 376,
serves the purpose of reducing the errors occuring during playback upon
the occurrence of substantial transitions in the vertical direction, i.e.
at the horizontal edges, as a result of the trisequential operation. The
predistortion substantially involves averaging of a plurality of lines of
the sequential signals.
The known playback circuit having a total of three delay lines is of
relatively complicated structure because individual signals which have
different amplitudes have to be combined to form the luminance difference
signal. This special requirement for different amplitudes also makes
matching of the components of this playback circuit relatively difficult.
SUMMARY OF THE INVENTION
It is an object of the present invention to simplify such circuit structure
and matching in a circuit of the above-described type.
This and other objects are achieved, according to the present invention, in
a playback circuit for a three-line sequential color television signal,
which includes a memory composed of three delay lines connected together
in series, each delay line producing a signal time delay equal to one
horizontal picture line scanning period, one end of the resulting series
arrangement being connected to receive the color television signal, and
four outputs connected, respectively, to the one end of the series
arrangement and to the output of each delay line to provide the undelayed
sequential signal and the sequential signal delayed by one, two and three
horizontal picture lines, respectively, a combining unit connected to the
four outputs to combine the signals thereat into a difference signal, and
an adding unit connected for adding the difference signal to the
three-line sequential signal, by constructing the memory for causing the
signals at the four outputs to have identical amplitudes, and by
constituting the combining unit of four electrically identical combining
components each connected to a respective one of the outputs and of
elements connected for reversing the polarity of the undelayed signal and
the signal delayed by three picture lines relative to the signal delayed
by one and two picture lines.
It can be mathematically proven that the particularly simple circuit
according to the present invention produces the same end result in the
signal combination as the known circuit, but with simpler circuitry. Due
to the fact that the four signals are combined at the outputs of the
series circuit of the delay lines with the same amplitudes and via
identical components, the circuit structure and matching are made much
simpler. This also avoids delay errors in the signals to be combined. The
combination can be with respect to signals at the video frequency or
carrier frequency. For carrier frequency combination, the simplified
circuit also substantially eliminates phase errors in the combined signals
.
BRIEF DESCRIPTION OF THE DRAWING
FIG. 1 is a block circuit diagram of a preferred embodiment of a playback
circuit according to the present invention.
FIG. 2 is a circuit diagram of a preferred practical embodiment of a
portion of the circuit of FIG. 1 for combining video frequency signals.
FIG. 3 is a circuit diagram of a preferred embodiment of a circuit portion
corresponding to that of FIG. 2 for combinding carrier frequency signals.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
In the circuit shown in FIG. 1, a three-line sequential signal coming from
a video record disc player is transmitted from a terminal 1 via a delay
member 2 provided for delay compensation and is fed to an adder stage 3
and, via a capacitor 4, to a modulator 5. The carrier signal for the
modulator 5 is generated in a quartz oscillator 6. The signal from delay
member 2 contains, in a lower frequency band, a luminance signal M and a
luminance difference signal .DELTA. M, .DELTA. M being a shorthand
designation of the sequential signal components R-M, G-M, B-M in the lower
frequency band, containing the color information, in each case M being the
luminance signal of the lower frequency band.
The circuit further includes an adder stage 7, three delay lines 8, 9 and
10, each producing a delay of one line scanning period, adder stages 11
and 12, a subtracting stage 13, and a circuit 14 including the usual line
frequency switch and PAL matrix. In circuit 14, a PAL chrominance carrier
F.sub.PAL is obtained in a known manner from the undelayed signal D.sub.0,
a signal D.sub.1 which appears at the output of line 8 and has been
delayed by one horizontal picture line period, and a signal D.sub.2 which
appears at the output of line 9 and has been delayed by two horizontal
picture line periods. This PAL chrominance carrier F.sub.PAL is added to
the luminance signal in adder stage 3 to form an FBAS signal. A complete
PAL-FBAS signal is then present at terminal 15.
In the circuit including stages 11, 12 and 13, signals D.sub.0, D.sub.1,
D.sub.2 and D.sub.3 are then combined to form signal F.sub..DELTA. M,
which is a carrier signal from oscillator 6 at the chrominance carrier
frequency modulated by the above-defined difference signal .DELTA. M. This
signal is demodulated in a demodulator 16, which receives the carrier
signal coming from oscillator 6, and fed, via a lowpass filter 17, as a
correction signal component -- .DELTA. M to adder stage 3. Thus the
luminance difference signal .DELTA. M in the lower frequency band is
eliminated in the manner explained in German Pat. No. 22 07 021 and
corresponding U.S. Pat. No. 3,808,359. Between the output and input of the
series connection of the three delay lines 8, 9 and 10 a feedback path 18
is provided in the manner, and for the purpose, disclosed in German
Offenlegungsschrift No. 24 46 376.
It can be seen that, according to the invention, the signals D.sub.0,
D.sub.1, D.sub.2 and D.sub.3 which are combined have the same amplitudes
and are combined by means of identical components, i.e. in complete
symmetry, to form the signal F .sub..DELTA. M. It is assumed in this
connection that delay lines 8, 9 and 10 have no attenuation or that such
attenuation is always compensated by series-connected amplifiers. In FIG.
1 carrier modulated signals are being combined. The signals fed to stages
11 and 12 thus all have the same amplitude and phase.
In the circuit shown in FIG. 2 the signals which are combined are video
frequency signals. The signals at the four outputs of the series circuit
8, 9, and 10 are demodulated in demodulators 19, 20, 21 and 22,
respectively, demodulators 19 and 22 simultaneously effecting a polarity
reversal. This produces the correct matrixing. These signals are fed via
four identical resistors R to an input of an amplifier 23. The signal
appears at the output of amplifier 23 in a form similar to that at the
output of stage 13 of FIG. 1, i.e., as a signal .DELTA. M, but now in
video frequency form. If the circuit of FIG. 2 were employed in the
embodiment of FIG. 1, this signal can be fed directly to lowpass filter 17
so that demodulator 16 could be eliminated. Resistor 25 is provided to
give amplifier 23 a low input resistance.
FIG. 3 shows the corresponding circuit for signals modulated onto the
carrier. These are fed, as in FIG. 2, via four identical resistors R to
the input of amplifier 23. At its output amplifier 23 furnishes the signal
F .sub..DELTA. M, which corresponds to the identically marked signal at
the output of stage 13 in FIG. 1. The polarity reversal is here effected
by means of a bifilar-wound coil 24 whose center tap is grounded. One end
of coil 24 is connected to the amplifier signal input and to the resistors
R whose other ends are connected to the outputs of delay lines 8 and 9.
The other end of coil 24 is connected to the resistors R whose other ends
are connected to the input of line 8 and the output of line 10. The signal
passed to modulator 5 is the same signal as illustrated at the output of
delay member 2 and includes frequency portions M + .DELTA.M + H. This is
the original video output signal from the recorder.
It will be understood that the above description of the present invention
is susceptible to various modifications, changes and adaptations, and the
same are intended to be comprehended within the meaning and range of
equivalents of the appended claims.
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