Abstract:
Digital color signal processing circuitry includes a multiplier which multiplies two demodulated digital color-difference signals by a digital color-saturation signal to provide three time-division-multiplexed signal pairs, each of which is added to the digital luminance signal by an adder. The color-saturation-signal input of the multiplier is preceded by a second multiplier to which the color-saturation signal and multiplier factors stored in a memory (sp) are applied. These multiplier factors are permanently stored by the manufacture of the color-television receiver or can be varied or adjusted during the operation of the receiver. The three adders are followed by three digital-to-analog converters which provide the analog color signals.

Description:
BACKGROUND OF THE INVENTION 
     The present invention relates to a digital integrated circuit for a color-television receiver with digital signal processing circuitry which contains a first multiplier which multiplies two demodulated digital color-difference signals with a digital color-saturation signal using time-division multiplexing. 
     A digital integrated circuit of this kind is disclosed in the publication &#34;DIGIT 2000 VLSI-Digital-TV-System&#34;, March 1982, in the form of the description of the integrated circuits MAA 2100 and MAA 2200 on pages 4-3 to 4-5. In FIG. 4-2 on page 4-3, the above-mentioned multiplier is called a &#34;color-saturation multiplier&#34; because it is fed with the demodulated color-difference signals from the preceding stages and with the aforementioned digital color-saturation signal via a stage called &#34;IM bus interface&#34;. For the two color-difference signals, time-division multiplexing is used; the same applies to the delivery of the corresponding output signals to the two following digital-to-analog converters for the two analog color-difference signals. 
     As also described in the publication mentioned above, the two integrated circuits MAA 2100 and MAA 2200 form part of an IC set with which digital color-television receivers can be implemented. 
     SUMMARY OF THE INVENTION 
     We have discovered that the color-saturation multiplier of the prior art, besides being usable for this special purpose, can be multiplexed so as to simplify the overall arrangement for digitally processing the received picture signal. Accordingly, an object of the invention is to improve the prior art digital circuit so that the multiplier can be multiplexed. 
     An advantage offered by the invention is that the analog R-G-B matrix used in the prior art arrangement to generate the analog color signals can be dispensed with because these analog color signals appear at the outputs of the digital-to-analog converters used in the invention. In a modified form, the invention offers the added advantage that the tint-control function required in NTSC color-television receivers can be realized with the color-saturation multiplier as well. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The invention will now be explained in more detail with reference to the accompanying drawings, in which: 
     FIG. 1 is a block diagram of an embodiment of the invention; 
     FIG. 2 is a block diagram of another embodiment of the invention; and 
     FIG. 3 is a block diagram of an embodiment of the above-mentioned modification of the invention for NTSC color-television receivers. 
    
    
     DETAILED DESCRIPTION 
     In the figures, digital signals are designated by small letters, and analog signals by capital letters. 
     In the block diagram of FIG. 1, digital color-difference signals b-y, r-y, derived from the transmitted and received television signal in the known manner, are supplied to the multiplexer mx, whose output is connected to one of the two inputs of the first multiplier m1. Connected to the other input, to which the color-saturation signal is applied in the prior art arrangement mentioned above, is the output of the second multiplier m2, whose two inputs are, respectively, fed with the color-saturation signal s and connected to the output of the memory sp. 
     The first multiplier m1 provides three signal pairs b&#39;, b&#34;; g&#39;, g&#34;; r&#39;, r&#34; on a time-division multiplex basis. The first signals of the pairs are applied to the first inputs of the first, second, and third adders a1, a2, a3, respectively, and the second signals are applied to the respective second inputs. Each adder has a third input to which the digital luminance signal y is applied, which was derived from the transmitted and received television signal in the known manner. 
     The memory sp contains multiplier factors b1, b2; g1, g2; r1, r2, which are defined as follows: 
     b&#39;=s(b-y)b1, b&#34;=s(r-y)b2 
     g&#39;=s(b-y)g1, g&#34;=s(r-y)g2, 
     r&#39;=s(b-y)r1, r&#34;=s(r-y)r2. 
     As can be seen, it is possible to influence with these six multiplier factors the composition of the signals provided at the outputs of the three adders a1, a2, a3 and, consequently, the analog signals provided at the outputs of the three digital-to-analog converters d1, d2, d3 following the adders. 
     The multiplier factors b1, b2; g1, g2; r1, r2, or their numerical values, are permanently stored in the memory sp by the manufacturer of the color-television receiver, or they may be variable or adjustable during operation of the color-television receiver by a corresponding signal fed to the memory. Such adjustability may be considered to be provided by the above-mentioned tint control feature in NTSC color-television receivers, as will be described below. The variability of the multiplier factors contained in the memory sp may also be used to produce color effects in the picture, e.g., by generating, with a suitable circuit, a periodically or temporarily variable signal with which the transmitted and received color combination can be changed, e.g., turned into the complementary colors. Such a variable signal may also originate directly from the transmitted and received color-television signal, as is the case, for example, in a recent variant of the NTSC system, the so-called vertical interval reference (VIR) system, in which on the nineteenth line of each transmitted field, a reference signal for the correct color is transmitted which is used for automatic color correction in the receiver. 
     If conventional color-picture tubes are to be driven with an analog luminance signal Y according to the known equation Y=0.3R+0.59G+0.11B, the multiplier factors have the following decimal numerical values: 
     b1=1/b*; b2=r=0; g1=-0.19b*, g2=-0.51/r*; r2=1/r*, 
     where b* and r* are factors by which the blue- and red-minus-luminance signals, respectively, are multiplied at the transmitting end in accordance with the transmitter&#39;s color-television standard. For the PAL and NTSC standards, the values of these factors are b*=0.493 and r*=0.877, while those for the SECAM standard are b*=1.5 and r*=-1.9, as is well known. 
     In the aforementioned special variant of driving conventional color-picture tubes, the numerical values are thus stored in the memory sp by the set manufacturer depending on the television standard for which the color-television receiver is designed. The memory is preferably a static memory, particularly a read-only memory or any of the various kinds of programmable and reprogrammable read-only memories. 
     The digital circuit in accordance with the invention not only can be used to drive conventional color-picture tubes but also is capable of driving color-picture tubes whose color loci differ from those of conventional color-picture tubes that are driven with an analog luminance signal Y according to the above equation. Such color-picture tubes are driven by the following equation: 
     
         Y=0.3R&#39;R+0.59G&#39;G+0.77B&#39;B 
    
     and the multiplier factors have the following decimal numerical values: 
     B1=1/b*; b2=r1=0; g1=-0.19B&#39;/G&#39;b*, g2=-0.51R&#39;/G&#39;r*; r2=1/r*, 
     where the factors b* and r* have the same meaning as above. The embodiment just described thus permits nonstandard color-picture tubes to be used for signals transmitted by the usual television standards without the need for significant extra circuitry. 
     FIG. 2 shows a block diagram of the above-outlined variant of the invention in which the values of the multiplier factors b1 . . . r2 contained in the memory sp can be changed by application of an external control signal u. 
     FIG. 3 shows the block diagram of a modification of the digital circuit according to the invention for color correction (&#34;tint control&#34;) in NTSC color-television receivers. The memory sp contains numerical values for the two goniometric functions sin α and cos α and is controlled by a signal representing the corresponding argument α. The two multiplier factors g1 and g2 are zero, so that no values are stored for them, and the second adder a1 of FIGS. 1 and 2 is no longer necessary. The argument α is the phase angle between the digital blue-minus-luminance signal b-y and the color burst, which angle can be set by the user of the color-television receiver or adjusts itself automatically in the recent NTSC system mentioned above. 
     The remaining adders a1&#39; and a3&#39; in the modification of FIG. 3 are fed only with the signal pairs b&#39;, b&#34; and r&#39;, r&#34;, respectively, but not with the digital luminance signal y; the latter is fed to the second digital-to-analog converter d2&#39;, which converts it into the analog luminance signal Y. The two other digital-to-analog converters d1 and d3 convert the output signals of the two adders a1&#39; and a2&#39; into the analog color-difference signals B-Y and R-Y, respectively. 
     The three analog signals just mentioned are fed to the usual analog R-G-B matrix mt, whose outputs provide the analog color signals B, G, and R. 
     It should be noted here that in the modification of FIG. 3, the factors b* and r* of the arrangements of FIGS. 1 and 2 do not belong the values stored in the memory sp, as can be seen; they are taken into account in the known manner by a suitable design of the R-G-B matrix mt. 
     In the arrangement of FIG. 3, the multiplier factors have the following values: 
     B1=r2=cos α; b2=sin α; r1=-sin α; g1=g2=0. 
     The negative sine function for the multiplier factor r1 can be realized either by storing the corresponding values in the memory sp in the binary two&#39;s complement, for example, or by making the third adder a3&#39; switchable to &#34;subtraction&#34;.