DE3238506A1 - METHOD AND DEVICE FOR SUPPLYING VIDEO COMPONENT SIGNALS TO A CHANNEL AND FOR TAKING THE SIGNALS FROM THE CHANNEL - Google Patents

Description

RCA 77533 Sch / Vu
US Ser. No. 312,932
dated October 19, 1981

RCA Corporation, New York, N.Y. (V.St.A.)

Method and apparatus for supplying video component signals to a channel and for extracting the signals from the channel

The invention relates to the supply of video component signals to a channel and to extract the signals from the channel.

For certain recording or transmission channels, it is impossible due to insufficient channel bandwidth or due to non-linearities due to overlapping with the color subcarrier be to record a composite television signal or to transfer. In such cases it may be useful to record the luminance and color information separately or transfer. For the following description a recording device with a channel bandwidth of 2.5 MHz is assumed considered for recording. While a single channel is not enough to provide a composite NTSC signal with a bandwidth of 4.2 MHz, for example, would be to use two channels for separate recording and Reproduction of luminance and color signals possible.

The color components (I and Q) of an NTSC color television signal could so in a single recording channel by appropriate frequency modulation of a pair of carrier signals recorded with the component signals, while

rend the luminance signal is recorded by frequency modulating a single carrier in a second channel. However, when the color components of a PAL or SECAM signal (U and V or R-Y, B-Y) are recorded in a similar manner then the channel bandwidth may be insufficient, since U and V signals (or R-Y and B-Y signals) both bandwidths of 1.5 MHz have bandwidths of 1.5 MHz and 0.6 MHz for the signals I and Q. One possibility to partially overcome this problem consists in the alternating line-by-line recording Color component signals of adjacent lines, each signal having its full bandwidth in the line scan direction has, hereinafter referred to as the horizontal bandwidth. When playing back the missing components reconstructed by repeating an adjacent line or by averaging adjacent lines. However, there is still a problem here in that the bandwidth of the channel is in the direction perpendicular to the line deflection direction (hereinafter referred to as vertical bandwidth) is smaller than that of the original signal because of the alternating Lines of transmission of a specific component. Therefore, corruption occurs in the vertical direction as a result of which a straight diagonal line takes place as a stepped line, which is to be regarded as a disturbing phenomenon in the television system is.

It is therefore desirable to have a transmission system which has a Can transmit video signal in a low bandwidth channel without such corruption effects.

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According to one aspect of the invention there is a method or a device for supplying component video signals to a channel is provided, the vertical bandwidth at least one of the component video signals is limited and the component signals to the channel alternately line by line are fed.

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In another aspect the invention provides a method or a device for extracting signals from a channel, which this according to the method or have been fed with the device according to the first-mentioned aspect ", and finally for feeding the Signals of alternating lines from this channel or signals derived from it to the corresponding outputs »

For a better understanding of the invention and to explain how it is carried out in practice, reference is now made to the FIGS

accompanying drawings illustrated embodiments. games referenced. Show it?

Fig. 1 is a block diagram of an embodiment for a recording system according to the invention; Fig. 2 is a block diagram of an embodiment for a playback system for use with the recording system according to Fig. 1;

3 shows a block diagram of a further exemplary embodiment according to the invention; and FIG. 4 shows a block diagram of an exemplary embodiment for a playback system for use with the recording system according to Fig. 3.

In Fig. 1, input terminals 10 and 10a become color component signals U or V from a camera or other video signal source such as a PAL decoder, which decodes the composite signal into its components Y, U and V. The signal U is denoted by U (n + 1) (where η the line number starting with 1 at the top of the scanning raster) and a 1H delay line 12- (the delayed by one line duration) and a weighting resistor 14. The output signal of the delay line 12 is thus U (n), that is to say one line above U (n + 1).

Line U (n) is referred to as the current reference line and goes to weighting resistor 16 and the 1H delay line 18. The output of delay line 18 is therefore U (n-1) and it becomes the weighting resistor

-ιο ί fed. The resistors 14, 16 and 20 divide the amplitude of the supplied signals by 1/4. 1/2 or 1/4 and allow the respective signals to reach corresponding inputs of an adder 22. The output of the adder 22 is thus 1/4 U (n-1) + 1/2 U (n) + 1/4 U (n + 1), and this weighted average is recorded instead of the signal U (n) as at conventional line-by-line recording or transmission systems. This weighted mean value is formed from signal samples which are temporally spaced apart by multiples of H, and therefore the mean values occur in a vertical direction with respect to the position of the samples on the raster. Since the signal in the vertical direction is a mean value, the maximum rate of change in the vertical direction, and thus the vertical bandwidth, is reduced, and in this way signal distortions due to too much information in the vertical direction are eliminated. The output signal of the adder 22 reaches the contact 24 of the switch 26.

The circuit for processing the signal V at the input terminal 10a corresponds to the circuit described above for the signal U and is therefore given the same reference numerals, but provided with the addition "a". The 1H delay lines 12a and 18a, the resistors 14a, 16a and 20a and the adder 22a generate the signal 1/4 V (n-1) + 1/2 V (n) + 1/4 V (n + 1) at the output of the adder 22a, which is sent to the Contact 24a of switch 26 is reached.

A switch control generator 28 which, like those below Generators yet to be described can have a J-K flip-flop, are horizontal and vertical sync signals supplied, and at its output it generates a half-line frequency Switch control signal, which the electronic Switch 26 controls like the dashed one. Line. indicates. This horizontal sync signal controls the switch 26 in such a way that it receives the averaged output signal U from the adder during a horizontal line to an FM modulator 30 supplies, while the switch 26 in the next line

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averaged output signal V from adder 22a. That The vertical sync signal determines the starting position of the switch 26 with regard to the field or frame frequency, so that the switching sequence is fully defined with regard to the video signal. The FM modulator 30 delivers Carrier signal that is in alternating lines with the output signal is modulated to a recording head 32 which sequentially records the signal on a magnetic tape 34. Although illustrates linear recording for simplicity is is in a preferred embodiment. the tape wrapped around a drum in which the Head 32 is arranged and with which it rotates for spiral scanning. Also the luminance and sound signals . are conventionally recorded in FM modulation on other tracks. The luminance signal is supplied to the recording head 152 via an FM modulator 150.

Fig. 2 shows the block diagram of a playback circuit, which can be used for magnetic tape recording using the circuit of FIG. The band 34 with the recording passes the playback head 36, which sends an output to an FM demodulator 38 corresponding to the the signal recorded on the tape. The demodulated output signal from demodulator 38 has the for one line Form 1/4 U (n-1) + 1/2 U (n) + 1/4 U (n + 1) and becomes a 1H delay line 40 and a resistor 42 is supplied. The output of delay line 40 contains the Information recorded on the previous line, which has the form 1/4 V (n-2) + 1/2 V (n-1) + 1/4 V (n), the a 1H delay line 44 and contacts 50 and 56 from switches 48 and 54, respectively. The output signal delay line 44 is a signal recorded two lines before the signal currently being scanned by head 36 and has the form 1/4 U (n-3) + 1/2 U (n-2) + 1/4 U (n-1) and is fed to resistor 58. The resistances 42 and 58 divide the amplitudes of the applied signals by 2 and feed these reduced amplitude signals to one Adder 60, the output of which has the form

1/8 U (n-3) + 1/4 u (n-2) + 1/4 U (n-1) + 1/4 U (n) + 1/8 U (n + 1). This output signal arrives at contacts 46 and 52 of switches 48 and 54, respectively.

The switch control generator 62 receives horizontal and vertical synchronizing pulses, preferably from the luminance channel, fed because this channel has a larger bandwidth than the Has a color channel and therefore receives the pulse edges better. The generator 62 supplies the same half-line frequency switch control signal to switches 48 and 54, which corresponds to switch 26- from switch control generator 28 in the recording circuit according to Fig. 1 had been supplied. The control signal is symbolized by a dashed line. Are the switches 48 and 54 during one line in the position shown in FIG. 2, then the output signal appears at the output terminal 64 of the adder 60, that is to say the signal U, which is generated by further averaging by the delay lines 40 and 44 and resistors 42 and -48 and adder 60 again is formed, i.e. the two signals averaged over a line that were recorded during the Signal at output terminal 66 is the output signal of the delay line 40, that is to say the signal V averaged over one line. During the next line, the switches 48 and 54 is the opposite position from FIG. 2. In addition, the output signals from demodulator 38 are now the delay line 44 and the adder 60 signals V, while the output signal of the delay line 40 is a signal U " is. The arithmetic form of these signals is the same as noted in Fig. 2 except, of course, that the line numbers are increased by 1 in the brackets. Thus, the output terminal 64 is now supplied with the signal U from the delay line 40 supplied via the contact 50, while the output terminal 66 now receives the signal V from the adder 60 via the Contact 22 is supplied. During the next line the switches 68 and 52 return to their positions according to FIG return. For this reason, the signals U and V are always generated at connections 64 and 66.

It should be noted that both during the recording As well as playback, there is an average delay of 1H, resulting in a total delay of 2H. Ideally, the usual luminance channel " which includes playback head 154 and FM demodulator 156, have a 2H delay line 148 to compensate for the delay in the color channels. With an inexpensive one System but this does not have to be necessary »

Because only one color component is recorded during a given line becomes only a single adder and a single set of three amplitude weighting resistors in the Recording circuit according to Fig- 1 needs »The inputs of the Resistors are then placed between two sets of delay lines with the help of three single-pole changeover switches controlled by the generator 28.

3 and 4 show a compared to FIGS. 1 and 2 simpler System which uses only a 1H delay for recording in each channel and the one discussed above modified switch arrangement used. The transmission behavior is not as good as the previously explained system with a delay of 2H because the filters are in the FIGS. T and 2 are symmetrical about a reference line and thus result in a linear phase behavior. This means that a vertical transition in upward and downward direction is averaged (smeared) and not only in one direction, as is the case with the 1H system according to FIGS. In addition, the additional weighting factors result in FIGS. 1 and 2 show a better, that is to say more ideal, amplitude behavior. However, the system according to FIGS. 3 and 2 also results 4 still a considerable improvement over a conventional line-by-line recording or transmission system by comb filtering before the line-by-line recording transmission to reduce vertical distortions even in spite of using the simpler possible circuit, and this is of the utmost importance in portable devices.

The input terminals 70 and 70a of FIG. 3 are fed signals U (n) and V (n), respectively, which each form 1H delay lines 72 and 72a arrive and are given to switch contacts 74 and 76, respectively. The output signals from the delay lines 72 and 72a are signals U (n-1) and V (n-1) which are sent to the respective contacts 78 and 80 of the Switch 84 are given. Vertical and horizontal sync pulses are fed to the switch control generator, and it provides a half-line rate switch control signal to control switches 82 and 84, such as the dashed line Line shows. The output signal of the switch 82 thus receives the signals U (n) and V (n) alternately, while the Output signal from switch 84 contains alternating lines of signals U (n-1) and V (n-1). These output signals are with With the help of resistors 88 or 90 reduced in amplitude by a factor of 1/2 and then the adder fed, the output signal in a line 1/2 U (n) +

1/2 U (n-1) and on the next line 1/2 V (n + 1) + 1/2 V (n) is (the numbers in parentheses for the Signal V has meanwhile moved forward by 1), and these signals reach the FM modulator 30. The output signal this modulator is fed to the recording head 32, which records it on the moving tape 34.

Fig. 4 shows a playback circuit for use with the recording circuit of Fig. 3. The tape 34 moves past the playback head 36, the output signal of which is a FM demodulator 38 is supplied. The demodulated output signal of the demodulator 38, which is 1/2 U (n) in a line + 1/2 U (n-1), contacts 96 and 100 of switches 104 and 106, respectively, and a 1H delay line 94 are supplied. The output of delay line 94 contains the information recorded on the previous line, viz 1/2 V (n-1) + 1/2 V (n-2) and is applied to contacts 98 and 102. The switch control generator 62 provides a half-line rate Signal to control switches 104 and 106, as indicated by the dashed line. Are the switches in the positions shown, the signal U is then produced at the output terminal 108 and the signal at the output terminal 110

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Signal V. During the next line, the demodulator 38 supplies a signal V, while the delay line 94 is on Signal U delivers. Since the switches 104 and 106 are now in the opposite position compared to FIG. 4, arise at the output connections 108 and 110 continue to alternate between rows Signals U or V.

It should be noted that any combination of the Pre- and post-filtering circuits can be applied. For example, the recording circuit according to FIG in a portable device, while the playback circuit according to FIG. 2 for a studio playback machine is preferred. Furthermore, each device is capable of synchronizing the switch positions with the field or frame rate useful, even if frame alternation is desired, so that one can use vertical interleaving in the color channels of 4: 1. Such interleaving would enable future quality improvements where frame memories and time averaging is applied in reproducing the recorded information. Farther the system can be used to transmit video signals in channels other than recording circuits. Be it also mentions that the term "vertical" used in the description and claims is meant "perpendicular to the line scan direction".

Claims (25)

10 PATENTS WALTE ,; «" .. "DR. DIETER V. BEZOLD DIPL. ING. PETER SCHÜTZ DIPL. ING. WOLFGANG HEUSLER MARIA-THERESIA-STRASSE 22 POST BOX 86 02 60 D-8QOO MUENCHEN 86 APPROVED BY THE EUROPEAN PATENT OFFICE EUROPEAN PATENT ATTORNEYS MANDATA1RES EN BREVETS EUROPgENS TEL1EFON 089/4 70 60 06 TELBEZ S22 U.S.A. Ser "No. 312,932 dated October 19, 1981 RCA 'Corporation, New York, N.Y. . (V.St.A.) Claims 1) Method of supplying video component signals to a channel, characterized that the vertical bandwidth of at least one of the component video signals (U or V) is limited and the component signals are fed to the channel one by one line. 2) Method according to claim 1, characterized in that that the vertical bandwidth of all component video signals (34) is limited. 3) Method according to claim 1 or 2, characterized in that the or each component signal (U, V) before the Signal feed of alternating lines to the channel (3 4) is limited in bandwidth. 15th OSTSCHECK MÖNCHEN NO. 69148-800 BANK ACCOUNT HYPOBANK MÖNCHEN (BLZ 7OO 200 40) KTO. 60 60 2S7 378 SWIFT HYPO DE MM 4) Method according to one of the preceding claims, characterized in that the limitation of the vertical bandwidth the formation of a weighted combination of a line of a component video signal with at least one neighboring line Line includes. 5) Method according to claim 4, characterized in that a line (Un) of a component video signal is weighted and that the preceding line (Un-1) and the following line (Un + 1) are weighted and that a combination of the weighted lines is formed (for example 1/4 Un-1 + 1/2 Un + 1/4 Un + 1). 6) Method according to one of the preceding claims, characterized in that the component video signals are PAL component color signals (U, V) are. 7) Method according to one of the preceding claims 1 to 7, characterized in that the component video signals are SECAM component color signals. 8) A method for extracting signals from a channel, which this according to the method of one of the preceding claims 1 to 7 have been supplied, characterized by g e, that at least the signals of alternating lines derived from or from the channel Signals are fed to corresponding outputs. 9) Method according to claim 9, characterized in that combinations of the signals of alternating lines of the Channel can be weighted before the weighted combinations are fed to the corresponding outputs. 10) Method according to claim 9, characterized in that that a component signal (e.g. 1/4 Vn-2 + 1/2 Vn-I + 1/4 Vn) from the channel that is assigned to a line, one (V) of the outputs is supplied and that a weighted combination of the component signals from the channel which the the preceding line and the following line are assigned to another output (U). 11) Device for supplying component video signals to a channel characterized by a facility for limiting the vertical bandwidth of at least one of the component video signals (10, 12, 14, 16, 18, 20, 22) and for feeding (24, 24a, 26) the signals in alternating lines to the channel (34).
10 12) Device according to claim 11, characterized by a device for limiting the vertical bandwidth of all component video signals « 13) Device according to claim 11 or 12, characterized in that that the limiting means means means for forming a weighted combination of a line of a Component video signal with at least one adjacent line (Figs. 3, 72,88,90,92). 14) Device according to claim 13, characterized in that that the limiting device comprises a device for forming a weighted combination of a line (Un) of a component video signal with the previous line (Un-1) and with the following line (Un + 1) (Fig. 1, 10,12, 14,16,18,20,22). 15) Device according to claim 13, characterized in that the limiting device (Fig. 3) is a delay line (72) with an input and an output and a delay of one video line, a combinatorial circuit (92) and weighting resistors (88,90) for coupling the input and output of the delay line to the Combination circuit for forming a weighted combination of a line of the component video signal with an adjacent one Line includes. 16) Device according to claim 14, characterized in that that the limiting device (Fig. 1) is a series connection of two delay lines (12, 18) with an input, has an output and a connection point between both delay lines and that each delay line has one Has a delay of one video line duration (1H), also one Combination circuit (22) and weighting resistors (14, 16, 20) which connect the input, the output and the connection point to the combination circuit to form the weighted combination of one line (Un) with the following line (Un + 1) and the preceding line (Un-1) 17) Device according to claim 13, characterized in that that the limiting device each series connections of two delay lines (12, 18) for the component signals comprises, to which the component signal is fed at an input (10) and which have an output and a connection point between the delay lines, that each line has a delay of one video line duration (1H), and that for all the series connections a common one Combination circuit (22) is provided, the output of which to the channel and all three series circuits common Weighting resistors (14,16,20) are connected for coupling the input, output and connection point each of the series circuits with the combination circuit, and that the supply circuit receives the component signals from the series connections each one by one line to the resistors. 18) Device according to one of claims 11 to 17, characterized characterized in that the supply circuit has at least one two-pole changeover switch (24,24a, 26, Fig. 1) and one Switch control means (28) for synchronizing the operation of the switch with the picture line repetition period having. 19) Device for extracting signals from a channel, which the signal by means of a. Device according to have been supplied to one of claims 1 to 18, characterized in that at least a device (Fig. 4, 94, 96, 98, 102, 104, 106) for feeding the signals with alternating lines from the channel, or signals derived therefrom, to corresponding outputs. - 20) Device according to claim 19, characterized in that it has a device (Fig. 1, 40,42,44,58,60) for the formation contains weighted combinations of the line-wise alternating signals in the channel and that the feeding device (46,48,50,52,54,56,62) 'supplies the signal combinations to the outputs (64,66). 21) Device according to claim 20, characterized in that the feed device has an output (66) a signal (1 / 4V (n-2) + 1/2 V (n-1) + 1/4 V (n1) from the channel which is assigned to a row and that the weighted Combinations forming circuit forms a weighted combination of signals in the channel which of the preceding and is assigned to the following line (1/4 U (n-1) + 1/2 U (N) + 1/4 U (n + 1), 1/4 U (n-3) + 1/2 U ( n-2) + 1/4 U (n-1). 22) Device according to claim 21, characterized in that the weighted combinations forming the device a series connection of two delay lines (40, 44), each of which has a delay of one video line duration (1H) and a combination device (60) and weighting resistors (42,58), which input and output the series connection with the combination device. 23) Device according to one of claims 11 to 22, characterized characterized in that the component video signals are PAXi component color signals (U, V) are. 24) Device according to one of claims 11 to 22, characterized characterized in that the component video signals are SECAM component color signals. 25) Device according to one of claims 11 to 24, the is coupled to the channel, characterized in that the Channel a frequency modulator (150) for supplying the component signals with reduced bandwidth and in alternating lines, and a magnetic one coupled to the modulator Includes recording head (152).