KR900006475B1 - Television signal processing circuit - Google Patents

Abstract

The television signal processing circuit has an input device for receiving a television signal and a signal processing circuit which includes a video memory having a delay time equal to a vertical scanning period of the television signal or to an integer multiple of the period. A luminance signal and a chrominance signal of the video signal are separated, or the scanning line is interplated. A second signal processing circuit without a video memory is arranged in parallel with first signal processing circuit and responsive to the television signal. A selector in response to a television signal to be processed which does not conform with the standard colour levision signal, selects the output of the second signal processig circuit.

Description

TV signal processing circuit

1, 2 and 3 are all block diagrams showing the conceptual configuration of embodiments of a television signal processing circuit according to the present invention.

4 is a configuration diagram of an embodiment where the processing circuits of FIG. 3 are YC separation circuits.

FIG. 5 is a configuration diagram of one embodiment where the processing circuits of FIG. 3 are scan line interpolation circuits.

6 and 7 are block diagrams of embodiments of a color television receiver embodying the present invention.

FIG. 8 is a configuration diagram of one embodiment of the motion detection circuit 64 in the embodiment of FIG.

9 is a configuration diagram of another embodiment of the motion detection circuit 64 in the embodiment of FIG.

FIG. 10 is a circuit diagram of one embodiment of a scan line interpolation circuit in the embodiment of FIG.

FIG. 11 is a configuration diagram of another embodiment of the scan line interpolation circuit and the vertical horizontal synchronization signal separation circuit in the embodiment of FIG.

* Explanation of symbols for main parts of the drawings

2: first signal processing circuit 3: second signal processing circuit

4,48,92,112: switching circuit 7,54: judgment circuit

8,9,17,20,44,52,105,106,108,109: Counter circuit 10,64: Motion detection circuit

11,18,31,40,45,90,104,107,120: Addition circuit 14,39: Line memory

15,80: frame memory

16,19,23,26.43,81,88: Subtraction circuit

21,32,77,84,85: bandpass filter

22,101,102,103: delay circuit

27,76,82,89: Low pass filter

28,34,83,86,87,93 absolute value circuit

29,91: conversion circuit 30,50: register

33,53: gate circuit 35: accumulation circuit

36: limit value circuit 35, 51: extraction circuit

41: 1/2 counting circuit 42: Feed memory

46,47: time compression circuit 60: A / D converter

61: clock generation circuit 62: identification circuit

63: YC separation circuit 65, 67: scan line interpolation circuit

66: demodulation circuit 68,69: D / A converter

70: matrix circuit 71: horizontal synchronization signal separation circuit

72: vertical synchronization signal separation circuit 73: display device

74,75,94: switch 65-1,65-2: signal processing circuit

110,111: memory 113,121: D / A conversion circuit

114, 115, 122: Synchronous separation circuit 123: Frequency double circuit

The present invention provides a television signal processing circuit, and more particularly, a television signal processing suitable for dealing with not only a standard color television signal transmitted from a broadcasting station but also a television signal whose time, phase, etc. are different from that of at least a part of the standard color television signal. It is about a circuit.

Delay means having a delay time equal to or longer than the vertical scanning period of a television signal (e.g., a frame memory or a feed memory) can be realized at a small and low cost by the development of single-chip integrated circuit technology. Various processing circuits have been put into practical use.

For example, a signal processing method in which a color television signal is separated into a luminance signal and a chrominance signal using a frame memory, or an interlaced scan television signal is sequentially converted into a scan signal by interpolating scan lines using a feed memory is used. Known.

In the above-described signal processing circuit using a picture memory having a delay approximately equal to the vertical scanning period of the television signal or an integer multiple thereof, such as a feed memory or a frame memory, when the input television signal is a signal conforming to the standard color television system. A high quality output signal is obtained. However, in the case of dealing with output signals such as widespread home VTRs, these signals deviate from standard color television signals such as the time axis fluctuates greatly or the color single-carrier frequency and the scanning frequency are not in a predetermined relationship. It is becoming. Therefore, in the signal processing using the delay period or the frame period, correct processing cannot be performed. For example, in the separation of luminance and color using a frame memory, the phase of the color carrier should be inverted (different 180 °) from the signal before one frame period, but signals from home VTRs are not. Cannot separate accurate luminance signal and color signal. In addition, in the scan line interpolation using the feed memory, the feed period is not constant and an accurate interpolation signal cannot be obtained.

As a result, a processing circuit having an image memory such as a feed memory or a frame memory has a problem that, when the signal of the home VTR is processed, only a very degraded signal can be obtained.

The main object of the present invention is to accurately handle a standard color television system, that is, a color television signal having a constant relationship between the frequency of the line scanning frequency and the color carrier frequency, that is, a television signal not conforming to the standard color television system. A signal processing circuit having an image memory is provided.

In order to achieve the above object, the present invention provides a standard color television system in which a first signal processing circuit having an image memory such as a feed memory or a frame memory and a second signal processing circuit having no image memory are provided in parallel. In the case of processing a signal that is not quasi, it is characterized by having a switching means for selecting the second signal processing circuit.

In a preferred embodiment of the present invention, an output TV signal including a synchronization signal is processed and processed by a signal processing circuit that is approximately equal to or greater than the vertical scanning period of the delay time between the input TV signal and the output TV signal. The synchronization signal is separated from the TV signal, and the TV signal processed by the separated vertical and horizontal synchronization signals is displayed on the display value of the monitor. As a result, even a TV signal with jitter or the like can be stably displayed with only the synchronous separation circuit on the output side of the signal processing circuit without providing a new synchronization signal addition circuit in front of the signal processing circuit. .

In addition, the clock signal for operating the signal processing circuit is phase-locked to a specific signal in the blanking period of the input color television signal, and when the television signal to be processed is a non-standard television signal, such as a YC separation circuit or a scan line interpolation circuit. The signal processing circuit is an in-process processing circuit.

As a signal in the blanking period, a horizontal synchronization signal or a color burst signal is used.

In the case of using the horizontal synchronizing signal, YC separation needs to be performed by the intra-process, but scanning line interpolation can be performed without causing degradation of the adaptive adaptive interpolation.

In the case of phase synchronization with the color burst signal, both YC separation and scanning line interpolation are performed in the in-field processing, and a horizontal synchronization signal for deflecting the color display is extracted from the video signal doubled in clock speed.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings.

1 shows a conceptual diagram of the present invention. In FIG. 1, the television signal to be processed input to the terminal 1 is input to the first signal processing circuit 2 having an image memory and the second signal processing circuit 3 not having an image memory. The image memory is a memory having a delay time approximately equal to the vertical scanning synchronization of the television signal or an integer multiple thereof, as will be described later in detail.

The output of each signal processing circuit is selected by the switching circuit 4, and the switching circuit 4 is controlled by a control signal applied to the terminal 5 when processing a signal that does not conform to the standard color television signal. Is controlled so that the output of the second signal processing circuit 3 is selected and when the input television signal is a standard color television signal, the output of the first signal processing circuit 2 is selected and applied to the output terminal 6.

2 shows an embodiment of the present invention. In the figure, the first and second signal processing circuits 2 and 3 and the switching circuit 4 are the same as those in FIG.

In this embodiment, the television signal to be processed is input not only to the first and second signal processing circuits but also to a decision circuit 7 which determines whether or not the signal is a standard color television signal. The determination circuit 7 judges whether or not the color carrier signal and the scanning frequency are in a relation of a predetermined offset, or whether or not according to the standard color television system by whether or not there is a temporal variation in the feed period and the frame period. If it is determined in the determination circuit 7 that it does not conform to the standard color television system, the switching circuit 4 is controlled by the output signal, and the output of the second signal processing circuit is obtained at the terminal 6.

3 shows another embodiment of the present invention. In the figure, reference numerals 2 and 3 denote first and second signal processing circuits as shown in Figs. 1 and 2, respectively.

In this embodiment, the outputs of the first and second signal processing circuits 2 and 3 are input to the counting circuits 8 and 9, and are multiplied by k times and (1-k), respectively, and are added in the addition circuit 11. And output to the terminal 6. K denotes an operation coefficient that varies between 0 and 1 depending on the presence or absence of an operation.

The motion coefficient k is extracted by the motion detection circuit 10 as motion information included in the television signal. In the part of the still image where there is no operation, k approaches 1, and the ratio of the output signal of the first signal processing circuit using the image memory increases, and in the large part of the vigorously moving change, k approaches 0 and the second signal processing circuit The ratio of the output signal increases. If the television signal to be processed does not conform to the standard color television signal, the motion detection circuit is controlled by the control signal shown at the terminal 12 to forcibly set the operation coefficient k to 0 to perform the second signal processing. The output of the circuit 3 is obtained at the terminal 6.

The signal appearing at the terminal 12 may be a signal manually commanded or a signal which responds to input of an input television signal from a specific terminal, and moreover, an output signal of the determination circuit 97 shown in FIG. The same applies to the signal applied to the first terminal 5.

4 shows a more specific example of FIG. 3, which is an adaptive adaptive YC separation circuit for separating an NTSC color television signal into a luminance signal Y and a carrier color signal C using a frame memory and a line memory. The block diagram in the case where the present invention is applied to is shown.

In the NTSC system color television signal, the polarity of the carrier color signal C is inverted at every horizontal scanning period H, and the polarity of C is also used for the signal of the scanning line at the same position on the screen one frame before the delay of one frame 525H. Is inverting.

If the input television signal is X ₀ , and the signal obtained by delaying 1H in the line memory is X _-1 and the signal delayed by 525H in the frame memory is X _-525 , the carrier color signal C ₁ is used in the first signal processing circuit.

Can be extracted as. Here, H _BPF represents transfer characteristics of a band pass filter for extracting a signal of a carrier color signal band. Meanwhile, in the second signal processing circuit, the carrier color signal C ₂ is

Can be extracted as. Therefore, the desired carrier color signal (C) obtained by mixing C ₁ and C ₂ by the operation coefficient (k) is obtained by parallelizing equations (1) and (2) as follows.

Is obtained. 4 shows the luminance signal Y by obtaining a carrier color signal by specifically calculating equation (3) and subtracting it from the original NTSC signal. That is, the NTSC signal X ₀ input to the input terminal 13 obtains the 1H delayed signal X ₋₁ in the line memory 14 and the 525H delayed signal X ₋₅₂₅ in the frame memory 15.

The outputs of the line memory 914 and the frame memory 15 are subtracted by the subtraction circuit 16, and the result of subtraction is multiplied by the counting circuit 17 by k times. The operation of the part of parentheses {} in 3) can be realized.

Therefore, in the subtracting circuit 19, the output of the adding circuit 18 is subtracted from the input signal X ₀ and halved by the counting circuit 20 and inputted to the band pass filter 21 to input the carrier color signal band. Extracting only the component yields the desired carrier color signal C, which is the calculation of equation (3). In addition, subtracting the input NTSC signal from the delay circuit 22 by the same time as the operation delay time of the band pass filter 21 by the subtraction circuit 23 subtracts the C signal from the operation adaptation to the desired luminance signal Y. ) Is obtained.

In the present embodiment, the operation coefficient k is obtained by subtracting the difference signal between frames from the subtraction circuit 926, extracting the low frequency component thereof by the low pass filter 27, and taking its absolute value from the absolute value circuit 28. The motion information is obtained at zero in the still picture portion and at an amplitude in accordance with the change in luminance of the frame in the motion picture portion. When the operation information signal is input to the conversion circuit 29 composed of a read only memory (ROM) or the like, the operation coefficient k is obtained in the register 30.

The signal input to the input terminal 13 has jitter in the signal due to the mechanical time variation of the signal VTR from the home VTR, etc., and disappears in the exact reverse polarity phase relationship in the signal before one frame. Therefore, by observing the sum signal between the frames of the burst part, if there is no signal, it can be seen that a signal conforming to the standard color television system of NTSC is input. Is determined. In the embodiment of FIG. 4, the addition circuit 31 calculates the sum signal between the frames, records it in the bandpass filter 32, extracts the subcarrier signal components, and extracts the gate signal representing the burst signal period in the input signal. The gate signal obtained by the extraction circuit 37 gates only the burst portion in the gate circuit 33, takes its absolute value from the absolute value circuit 34, accumulates the burst period in the leakage chamber 35, and sets the value to the limit circuit. If a signal greater than or equal to the threshold value is detected by comparing with the predetermined value at (36), it is determined that the signal is a non-standard signal, and the register 30 is reset to force the operation coefficient k to zero. This realizes the YC separation operation without using the output of the frame memory.

FIG. 5 shows another specific circuit example of the third embodiment of the present invention, in which the present invention is applied to a signal processing circuit for converting interlaced television signals into motion-adjusted scan line interpolation and sequentially converting them to scan television signals. Another example is shown. In the figure, the interlaced-scanned television signal input to the terminal 38 is input to the line memory 39 for delaying 1H and the feed memory 42 for delaying 263H and displayed on the screen relative to the current signal Z ₀ . The signal Z 'of the interpolation scan line immediately above is obtained by the following operation adaptive calculation. That is, in the first signal processing circuit, the interpolation signal Z ₁ ′ is created as the signal 263H delayed front feed signal Z _-263 which is the scanning line at the same position.

Z ₁ '= Z _-263 (4)

On the other hand, in the second signal processing circuit, the interpolation signal Z ₂ ′ is created as an average value of the current signal Z ₀ and the 1H delayed signal Z ₋₁ .

The obtained interpolation signal Z 'is obtained by mixing Z ₁ ′ and Z ₂ ′ with the operation coefficient k described in the fourth embodiment as follows.

The addition circuit 40, the half counting circuit 41, the subtracting circuit 43, the counting circuit 44, and the adding circuit 45 in FIG. 5 are the operation coefficient k shown in the register 50. The circuit which obtained the interpolation signal Z 'by performing calculation of Formula (6) under control of is shown. The signal Z ₀ of the current scan line and the signal Z ′ of the interpolation scan line are compressed in half of the time axis in the time compression circuits 46 and 47, and the switching circuit 48 is switched in units of time-compressed scan lines. At 49, the horizontal scanning period is 1/2, and a signal of sequential scanning is obtained, which scans the total scan line between the feed periods of the input television signal.

When the television signal inputted to the terminal 38 is a time-base fluctuation signal from a home VTR or the like, that is, a non-standard television signal, the register 50 is reset to force the operation coefficient to zero and the line average interpolation. Is obtained as an interpolation signal. In the present embodiment, the presence or absence of time axis variation is determined by extracting the start signal of the vertical synchronization of the television signal Z ₀ from the extraction circuit 51 and performing the period of the vertical synchronization signal in the counter circuit 52 which operates as a clock signal of the sample frequency. It measures and supplies the measurement value of a vertical scanning period from the gate circuit 53 to the determination circuit 54. The determination circuit 54 determines that the signal conforms to the standard television system if the measured value is equal to the predetermined value. If it is not the same, the register 50 is reset by determining that the signal of large time axis variation that does not conform to the standard method is large.

In the determination method of the embodiment of FIG. 5 described above, in addition to the color television signal of the standard system such as NTSC, a mono television or other color television signal (e.g., a signal multiplexed with a luminance signal by time compression of a component signal or a chrominance signal) Applicable to

In addition, when the judging circuit of the fourth embodiment and the judging circuit of the fifth embodiment are juxtaposed, and it is determined that either of the determination results is a signal that does not conform to the standard method, it is possible to switch to the second processing method. A signal processing circuit capable of coping with is obtained.

In addition, as apparent in the configuration of the embodiment, it is obvious that the first and second signal processing circuits can be simplified in the circuit by sharing common parts thereof and sharing only substantially different parts thereof, and the specific configuration is limited to the embodiments. It is not.

Also, in the embodiments of Figs. 2 and 4 and 5, a determination circuit is provided to automatically determine whether or not a signal conforming to the standard system from an input television signal, but a plurality of input terminals are provided and inputted to a specific terminal. The signal may be a signal that does not conform to the standard method or a method of manually applying a switching signal from the outside.

As a specific embodiment of the signal processing circuit having an image memory, the present invention only shows a conversion circuit for a sequential scan signal of a YC separation circuit and an interlaced scan signal, but the present invention is not limited to this, but is not limited to this. The present invention is generally applicable to a signal processing apparatus generally having an image memory, such as an encoding device such as an encoder or a noise removing circuit.

Although embodiments of the present invention (FIGS. 4 and 5) have described NTSC system television signals, it is obvious that other systems (PAL security, etc.) can be applied.

6 is a block diagram showing the configuration of another embodiment of a color television signal processing circuit according to the present invention.

In the figure, the NTSC composite color television signal input to the input terminal 1 is digitalized by the A / D converter 60. The input NTSC television signal is also input to the clock generation circuit 61, and the input NTSC signal. The clock signal phase locked to the color burst signal is outputted to the A / D converter 60 or the like. The output of the A / D converter 60 is input to the motion adaptive YC separator circuit 63 and the motion detection circuit 64 using the frame memory and the line memory. The YC separated luminance signal Y is input to an operation-adaptive scan line interpolation circuit 65 using a feed memory and a line memory, and converted into a sequential scan signal at double speed. The YC separated carrier color signal C is demodulated by the color difference signal in the demodulation circuit 66 and converted into a sequential scanning signal at a double speed in the scan line interpolation circuit 67 using the line memory. The obtained sequential scan signal is returned to an analog signal by the D / A converters 68 and 69, and is converted into three primary color signals (R, R, green G, and blue B) by the matrix circuit 70 to the output display device 73. Is entered.

In addition, the horizontal synchronizing signal separation circuit 71 separates the horizontal synchronizing signal HD from the output of the D / A converter 68 after 22x speed and applies it to the display device 73.

The vertical synchronization signal separation circuit 72 separates the vertical synchronization signal VD from the Y signal separated by the YC separation circuit 63 and applies it to the display device.

In the above embodiment, the operation adaptive YC separation circuit 63, the scan line interpolation circuit 65, the motion detection circuit 64, and the identification circuit 62 for discriminating whether the input television signal is a standard or nonstandard television signal The circuits shown in Figs. 4 and 5 described above are used.

As described above, in the identification of nonstandard signals, (1) a method of forcibly turning to a nonstandard signal mode by manual operation, and (2) a dedicated input terminal for inputting a nonstandard signal and a nonstandard signal is input thereto. Method of making signal signal, (3) Non-standard when phase is changed between frames by monitoring the synchronous signal part of input color television signal (specifically, the number of clocks in frame period is counted and different from predetermined clock number) The signal mode method or the sum signal between the lines of the color burst part is monitored. If the signal of the color carrier component is more than a certain level, the offset relationship is lost. Therefore, the presence or absence of this signal is used to determine the identification signal. I can stay.

The identification circuit 62 of FIG. 6 is a block diagram corresponding to this (3).

In addition, in the YC separation circuit 63 or the scan line interpolation circuit 65, a signal delay occurs for processing, and a synchronization signal (especially a horizontal synchronization signal) for deflecting and driving the display device 73 is extracted from the input color television signal and displayed. When supplied to the device 73, a time shift occurs between the video signal and the synchronization signal. When a standard signal with no temporal variation is input, this deviation does not affect the reproduced image.

On the other hand, in the case of a non-standard signal, this deviation is caused to fluctuate left and right of the screen with time variation. In order to avoid this, in the embodiment of FIG. 6, the A / D converter 60 includes the synchronization signal and digitally synchronizes the horizontal synchronization signal separator circuit 71 from the output signal of the D / A converter 68 after double speed. The signal HD is separated to thereby drive the display device 73. Due to this, since the video signal and the horizontal synchronizing signal supplied to the display apparatus have the same time variation component without time deviation, this variation is eliminated on the screen and an accurate reproduction image is obtained.

FIG. 7 is a diagram showing a configuration of an embodiment of the YC separation circuit section in another embodiment of the television signal processing circuit of the present invention, and the same reference numerals are used for parts corresponding to FIG.

In particular, the present embodiment is effective when a clock signal of phase lock is used for the horizontal synchronization signal of the input television signal as the clock signal of the signal processing circuit. That is, the clock signal generation circuit 61 of FIG. 7 generates a clock signal phase locked to the horizontal synchronizing signal of the input television signal.

When the identification circuit 62 determines that the input television signal is a standard television signal, the switches 74 and 75 are controlled to select the outputs Y and C of the YC separation circuit 63. The configuration of the YC separation circuit 63 is the same as that shown in FIG.

When the identification circuit 62 determines that the input television signal is a non-standard television signal, the switches 74 and 75 select the outputs Y 'and C' of the YC separation circuit 63 '.

In this case, the luminance signal Y 'is extracted by the low pass filter 76 and the carrier color signal C' is extracted by the band pass filter 77 in the input television signal. In the case of non-standard signals such as home VTRs, since there is no offset relation that the phase of the color carrier signal is inverted between lines, YC separation is performed by simple in-line processing by a low pass filter and a band pass filter.

When the input color television signal is a signal from a home VTR or the like, there is a change in the time axis, so that the signal before the frame period or before the period of the period cannot be used. This can be realized by setting the value of the operation coefficient k to " 0 " (video fairy mode) Fig. 8 shows the configuration of one embodiment of the motion detection circuit 6. That is, the input color television signal X ₀ and The absolute value signal of the low frequency component of the frame difference is obtained by the subtraction circuit 81, the low pass filter 82, and the absolute value circuit 83 using the signal X _-5 delayed by the frame memory 80. The operation information signal My of the low frequency component is obtained, while the frame difference signal of the absolute value of the carrier color signal band component is obtained from the band pass filters 84 and 85, the absolute value circuits 86 and 87, and the subtraction circuit 88. .

When this is demodulated by the absolute value circuit 93 and the low pass filter 89, the operation information signal Mc of the color difference signal is obtained. Both of these signals are added by the addition circuit 90 and converted by the conversion circuit 91 into the operation coefficient k. If the input signal in the switching circuit 92 is a non-standard signal such as a home VTR, the YC separation circuit 63 sets the operation coefficient to "0" by the control of the identification signal S (described later). If necessary, the scan line interpolation circuit 65 and the like are used together as the in-process processing mode.

FIG. 9 is a circuit diagram of another embodiment of the operation detection circuit 64. The configuration of the output side is changed from blocks 83 and 89 in FIG. 8, and the input side from the block is the same as that of FIG. The operation information My of the low frequency component of the luminance signal is obtained from the absolute value circuit 83 and the operation information Mc of the color difference signal is obtained from the low pass filter 89. When the input television signal is a standard television signal, the switch 94 is connected to the upper side by the output signal of the identification circuit 62, and the sum of the signals My and Mc is obtained and converted by the adder circuit 90. The circuit 91 converts the operation coefficient. On the other hand, when the input television signal is a non-standard signal, since the carrier color signal has no condition that the polarity is inverted between frames, the operation information Mc cannot be used.

Therefore, the signal 94 inputted to the addition circuit 90 by connecting the switch 94 to the lower side by the non-standard signal identification signal S is forcibly set to a value of "0" (no operation).

When the clock signal is phase locked in the horizontal scanning period of the input television signal as described above, even if there is a time axis variation (jitter), the position on the image of each pixel is always constant, and the jitter component is eliminated. Therefore, it is only necessary to consider that the phase of the carrier color signal is not related to the offset between the lines.

YC separation is used as an in-line process, and an operation coefficient is extracted as a frame difference signal of low frequency components of luminance, and an operation adaptation using a feed memory is used as in the case of a standard television signal such as a scanning line.

10 shows the configuration of another embodiment of an operation adaptive scan line interpolation circuit 65. As shown in FIG.

In the diagram, the signal processing circuit includes an input television signal (V ₁₎ interpolated scanning line first signal (V ₁₎ and the input television signal nearly as 262H in the vertical scanning period from the (V ₁₎ (H is a periodic horizontal scan) from the delay a second said first and second signals (V 1, V ₂₎ and by the time compressed to one-half switched in units of the scanning lines of the time-multiplexed output signal (V ₂₎ a signal processing circuit (65-1) to obtain The signal processing circuit 65-2 obtains the TV signal V ₀ . In the signal processing circuit 65-1, the input TV signal V ₁ is input to the cascaded delay circuits 101, 102, 103 having delay times of 262H, 1H, and 262H, respectively, and one frame 525H with respect to the signal V ₁ . The average value (V _t ) with the delayed signal is obtained by the addition circuit 104 and the counting circuit 105. Meanwhile, the addition circuit 107 and the counting circuit 108 obtain the average destination V _s of the input / output signals of the delay circuit 102 having a delay time of 1H. The motion coefficient representing the motion information of the subject extracted from the motion detection circuit (not shown) by mixing the average signal V _t and V _s in the counting circuits 106 and 109 and the addition circuit 120. k) (0 k 1). The first TV signal V ₁ , which is a signal of the interpolation scan line, is

V ₁ = kV _t ++ (1-k) V _s

Can be displayed. The second signal V2 is a signal obtained by delaying the input TV signal by the delay circuit 101 by 262H. In the signal processing circuit 65-2, the two signals V ₁ and V ₂ are input to the memory 110 and 111 having a capacity of 1H, respectively, and read out twice, thereby compressing the time in half and switching circuit 112 When switching from unit to scan line and returning to the analog TV signal from the D / A conversion circuit 113, the terminal 116 obtains the output signal V _{0 to} be supplied to the display device.

When the input TV signal V ₁ is a nonstandard television signal having a large jitter such as VTR, the operation coefficient k described above is strongly set to zero. As a result, the signal V _t which is the average value of the scanning lines of the front and rear of the front and back is not used, and as the signal V ₁ , the average value V _s of the upper and lower scanning lines which are close in time are output. Therefore, as an image, the average signal of the upper and lower scanning lines displayed is displayed. On the other hand, since the signal V ₁ is an average value of the scan lines, the waveform of the vertical synchronization signal portion is disturbed and the extraction of the vertical synchronization signal becomes difficult. In the embodiment of Fig. 10, this is solved, and only the horizontal synchronizing signal HD is separated from the synchronizing separation circuit 114 from the output signal V ₀ so that the vertical synchronizing signal VD is obtained by the signal processing circuit 65-]. Is separated from the second output signal (V ₂ ) of the first synchronous separation circuit (115). The signal V ₂ is a signal obtained by simply delaying the input TV signal V ₁ by approximately vertical scanning period, and there is no disturbance of the vertical synchronization portion, and the vertical synchronization signal VD can be easily extracted.

FIG. 11 shows another embodiment in which the synchronization signal is extracted in the same signal processing circuit as in FIG. That is, the second signal V ₂ , which is the delay signal output from the signal processing circuit 65-1, is returned to the analog signal by the D / 'A conversion circuit 121, and the horizontal synchronization is performed by the synchronization separating circuit 122. The signal HD 'and the vertical synchronizing signal VD are separated. When the signal HD 'is doubled by the frequency double circuit 123, the desired horizontal synchronizing signal HD can be obtained.

10 and 11 show the input signal V ₁ as a separate luminance signal when used as the circuit 65 of FIG. 6, but may be a composite television signal including a synchronization signal.

Alternatively, a component signal such as red (R), blue (B), green (G) and the like including the synchronization signal may be used.

If the input television signal V ₁ is an analog signal, an A / D converter is required.

In the embodiment of Fig. 10, the horizontal synchronizing signal HD is extracted from the output side of the D / A conversion circuit 113, but it is also possible to digitally separate it from the input side of the D / A conversion circuit 113. However, in the case of digital signal separation, jitter in the horizontal direction is likely to occur due to distortion due to sampling. In the case of the vertical synchronizing signal VD, since the period is long, the influence of jitter due to the change of the table can be ignored, and the synchronizing separation circuit 115 can be constituted by a digital circuit.

Claims (8)

An input unit 1 for receiving a television signal; A first signal processing circuit (2) including an image memory having a delay time such as vertical scanning of the television signal or an integer multiple thereof, at least for separating luminance signals and color signals of the video signal or interpolating scan lines; A second signal processing circuit (3) provided in parallel with said first signal processing circuit without an image memory and responsive to said television signal; And selecting means for selecting an output of said second signal processing circuit if the television signal to be processed is not a standard color television system. 2. The apparatus according to claim 1, wherein said selection means comprises: a decision circuit (7) which determines whether or not a television signal supplied to said input unit is a standard color television signal; And a switching circuit 4 for selecting the output of the first signal processing circuit or the output of the second signal processing circuit in response to the output signal of the determination circuit indicating the type of the current color television signal. TV signal processing circuit. 2. The apparatus according to claim 1, wherein said selecting means includes a coefficient generating circuit (10) for generating coefficients corresponding to operation data of a television signal, and said coefficients to an output of said first signal processing circuit or an output of a second signal processing circuit. Coefficient multiplication circuit 8 or 9 to multiply, and coefficient control circuit 62 for forcibly setting the coefficient of the output of the coefficient generating circuit to a predetermined value when the television signal to be processed is not a standard television signal. TV signal processing circuit. The television signal processing circuit according to claim 1, wherein said input section has a clock signal generation circuit (61) for generating a clock signal having a phase synchronized with a horizontal synchronizing signal of an input television signal. The television signal processing circuit according to claim 1, wherein the input unit has a clock signal generation circuit (61) for generating a clock signal in phase synchronized with a color burst signal of an input color television signal. . The television signal processing circuit according to claim 1, further comprising a deflection signal generator (114) for separating at least a horizontal synchronizing signal from an output of said selection means. An input unit 60 for converting a color television signal into a digital signal, a YC separation circuit 63 for receiving a digital color television signal generated by the input unit and separating it into a latitude signal and a carrier color signal, and scanning the output of the separation circuit In a television processing circuit comprising a scanning line interpolation circuit 65 for converting a player into a doubled signal, and a display device 73 for converting the output signal of the scanning line interpolation circuit into an analytic signal and displaying it on a display screen, The YC separation circuit comprises a first mixing circuit for obtaining a single color signal separated from the luminance signal by mixing the first color signal obtained from the difference signal between the frames of the input color television signal and the second color signal obtained by the feed-to-process ( 117, wherein the scan line interpolation circuit comprises: a first compression circuit 46 for directly time-compressing an input signal supplied to the line interpolation circuit; A second mixing circuit 44 for mixing a signal averaged over periods apart and a signal having a one-cycle period delay, a second compression circuit 47 for time-compressing the mixed interpolation signal, and the first and second signals. A switch 48 for switching the output of the compression circuit to one half of the horizontal scanning period of the input color television signal; The control means S controls the YC separation circuit that generates only the second carrier color signal when the input television signal is a non-standard television signal, and the second compression circuit of the scanning line interpolation circuit averages the signals separated by one line period. And a television signal processing circuit for receiving only. 8. The television signal processing circuit according to claim 7, wherein the television signal processing circuit has an operation detection circuit (64) for detecting the operation of an image from an input color television signal, and the mixing ratio of the first and second mixing circuits is controlled by the output of the operation detection circuit. Television signal processing circuit characterized by the above-mentioned.

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