JP2681996B2 - Image processing device - Google Patents

Description

The present invention relates to an image processing apparatus, and more particularly to an image processing apparatus for synchronizing line-sequential color difference signals.

[Conventional technology]

8A and 8B are configuration block diagrams of a conventional example of a signal processing circuit in a still video system, showing a luminance signal and a color difference signal, respectively. 8A, reference numeral 800 denotes an input terminal of a reproduced luminance signal reproduced from a magnetic sheet as a magnetic recording medium, 802 denotes a 1H (one horizontal scanning period) delay line, and 804 denotes a reproduced luminance signal or a delay line of the input terminal 800. A switch for selecting a delay signal by 802, 806 is an adder for adding and averaging the output of the switch 804 and the output of the delay line 802, 808 is a 1 / 2H delay line, and 810 is for selecting the outputs of the delay lines 802 and 808. A switch 812 is an output terminal of a selection signal by the switch 810. In FIG. 8B, 814 is an input terminal for the reproduction line sequential color difference signal reproduced from the magnetic sheet, and 816 is 1
/ 2H delay line, 818 is a switch for selecting the reproduction line sequential color difference signal of the input terminal 814 or the output of the delay line 816, and 820 and 822 are 1H
, 824 is a switch for selecting the output of the switch 818 or the output of the delay line 822, 826 is an adder for adding and averaging the output of the switch 824 and the output of the delay line 822, and 828, 830 are outputs of the delay line 820. Alternatively, switches 832 and 834 for selecting the output of the adder 826 are output terminals of the signals selected by the switches 828 and 830.

It is assumed that the reproduction luminance signal input to the input terminal 800 is sequentially represented as Y ₀ , Y ₁ , Y ₂ , Y ₃ , Y ₄ , Y ₅ , ... For each raster. The switch 804 normally selects the input terminal 800 side, and switches to the output side of the delay line 802 when a dropout occurs in the reproduction signal. In addition, the adder 806
Adds and averages the output of the switch 804 and the output of the delay line 802, and (Y ₀ + Y ₁ ) / 2, (Y ₁ + Y ₂ ) / 2, (Y ₂ + Y ₃ ) / 2, (Y
Outputs ₃ + Y ₄ ) / 2, (Y ₄ + Y ₅ ) / 2, .... Then, when reproducing the frame image of the magnetic sheet, the switch 81
0 always selects the output of the delay line 802, and when reproducing a field image, the switch 810 is switched for each field.

The reproduction line sequential color difference signals input to the input terminal 814 are sequentially RY ₀ , BY ₁ , RY ₂ , BY ₃ , RY ₄ , BY ₅ , RY ₆ , B for each raster.
Suppose it is written as Y ₇ , .... Switch 824
Normally selects the output of switch 818, but when dropout occurs, selects the output of delay line 822. The adder 826 adds and averages the output of the delay line 822 and the output of the switch 824 to obtain (RY ₀ + RY ₂ ) / 2, (BY ₁ + BY ₃ ) / 2, (RY
₂ + RY ₄ ) / 2, (BY ₃ + BY ₅ ) / 2, (RY ₄ + RY ₆ ) / 2, (BY ₅ + BY
₇ ) / 2, ... is output. By switching the switches 828 and 830, RY ₀ , (RY ₀ + RY ₂ ) / 2, RY ₂ , and (RY
₂ + RY ₄ ) / 2, RY ₄ , (RY ₄ + RY ₆ ) / 2, RY ₆ , ... are output and BY ₁ , (BY ₁ + B with 1H behind this at output terminal 834.
Y ₃ ) / 2, BY ₃ , (BY ₃ + BY ₅ ) / 2, BY ₅ , (BY ₅ + BY ₇ ) / 2, B
Y ₇ , ... is output. When reproducing the frame image of the magnetic sheet, the switch 818 always selects the input terminal 814 side, and when reproducing the field image, the switch 818 is switched for each field.

[Problems to be solved by the invention]

However, in the above conventional example, the delay lines 802, 808, 816, 820, 82
2 includes a large number of adjustment points in the manufacture and assembly of products, and over time, there are problems such as fluctuations in temperature characteristics, frequency characteristics, S / N ratio, etc., and deterioration of these delay lines. is there. In addition, considering a system configuration including an image memory, the circuit size is considerably increased.

Therefore, an object of the present invention is to provide an image processing apparatus that effectively utilizes the image memory instead of the delay line or the line memory that replaces the delay line to simultaneously output line-sequential color difference signals.

[Means for solving the problem]

An image processing apparatus according to the present invention has at least three output ports, and an image memory in which line-sequential color difference signals are written, and three adjacent line color difference signals are read from the three output ports. Address control means for controlling the read address of the image memory and outputs of two output ports other than the output port reading the color difference signal of the line located in the center of the adjacent three lines among the three output ports. Averaging means for averaging, and the color difference line-simulated from the output from the output port reading the color difference signal of the line located at the center of the three adjacent lines and the output of the averaging means. It is characterized by obtaining a signal.

[Action]

Since line-sequential color-difference signals are line-simultaneously used without using a delay line or a line memory, the number of circuit elements and circuit adjustment points can be reduced, and the factors for aging can be reduced.

〔Example〕

 Hereinafter, embodiments of the present invention will be described with reference to the drawings.

FIG. 2 is a block diagram showing the overall configuration of a still image recording / reproducing apparatus to which the present invention is applied. 210 is a video input terminal for inputting a video signal from the outside, 212 is a decoder for separating the video signal into a luminance signal and a chrominance signal, and 214 is a decoder 2
A switch that switches in synchronization with the horizontal synchronization signal _Hsync from 12 and converts the two color difference signals RY and BY output from the decoder 212 into line-sequential color difference signals. 216 and 217 are magnetic heads for reproducing video signals recorded on a magnetic sheet 215 as a magnetic recording medium, and 218 is a magnetic head 216 or the same.
A switch for selecting 217; 220, a switching control circuit for controlling the switching of the switch 218; 222, a reproduction circuit for demodulating the reproduction output of the magnetic heads 216, 217 to output a luminance signal and a line-sequential color difference signal; A switch 226 for selecting a luminance signal from the or a luminance signal from the reproduction circuit 222,
A switch for selecting a line-sequential color difference signal from the decoder 212 or a line-sequential color difference signal from the reproduction circuit 222.

Reference numerals 228 and 230 denote image memory circuits including an A / C converter, an image memory and a D / A converter. The image memory circuit 228 is for a luminance signal and the image memory circuit 230 is for a color difference signal. The image memory circuit 230 outputs the color difference signals simultaneously with the lines. 232
Is the output of the decoder 212 (a luminance signal and two color difference signals)
Alternatively, a switch that selects the output of the image memory circuits 228 and 230, 234 is an encoder that modulates and combines the luminance signal and color difference signal from the switch 232, and 236 is an output terminal of the combined video signal.

A switch 238 converts two color difference signals output from the image memory circuit 230 into a line-sequential signal, and switches in synchronization with the horizontal synchronization signal. 240 is a recording circuit that performs various processes for magnetic recording such as modulation on the luminance signal and chrominance signal from the image memory circuits 228 and 230 (more precisely, the switch 238), and 241 and 242 are recorded on the magnetic sheet 243. Circuit 240
244 is a switch for selecting the magnetic heads 241 and 242 for magnetically recording a signal from the magnetic head.

Reference numeral 246 denotes a synchronization separation circuit that separates a synchronization signal from the luminance signal selected by the switch 224, and reference numeral 248 denotes a PLL, such as a clock synchronized with the horizontal synchronization signal output from the synchronization separation circuit 246, a horizontal synchronization signal, and a vertical synchronization signal. A synchronization signal generation circuit for generating various synchronization signals, and a reference synchronization signal generation circuit 250 for generating various synchronization signals such as a clock, a horizontal synchronization signal, and a vertical synchronization signal using a crystal oscillator.
By turning on the reset switch 252, the reference synchronization signal generation circuit 250 is reset by an external horizontal synchronization signal, vertical synchronization signal, or the like. Reference numeral 254 denotes a selector for selecting an output of the synchronization signal generation circuit 248 or the reference synchronization signal generation circuit 250.
230 and the encoder 234. 256 is the circuit 248,2
A comparison circuit for comparing the fields of the synchronization signal output from the switch 50. The head switching by the switching control circuit 220 and the image memory circuit 2
Controls 28,230.

In FIG. 2, in a recording mode in which an externally input video signal is recorded on the magnetic sheet 243, the switches 224 and 226 select the decoder 212 side. The input signal of the input terminal 210 is separated into a luminance signal and a chrominance signal by a decoder 212, the luminance signal is passed through a switch 224 to an image memory circuit 228, and the chrominance signal is line-sequential by a switch 214.
Applied to 30. It is stored in the image memory circuits 228 and 230 by operating a recording command key (not shown).

At this time, the selector 254 selects the synchronization signal generation circuit 248, and the image memory circuits 228 and 230 and the encoder 234
It operates according to the synchronization signal from 248. The magnetic sheet 2
The motor (not shown) for rotating 43 is always rotating in synchronization with the vertical synchronization signal output from the reference synchronization signal generation circuit 250. When the reset switch 252 is turned on, an external reset state is set. Synchronizes with the input video signal.

Next, the selector 254 selects the reference synchronization signal generation circuit 250, and the image memory circuits 228, 230 and the encoder 234 operate according to the synchronization signal. The image memory circuits 228 and 230 are in a reading state, and output a luminance signal and a color difference signal. The color difference signal is line-sequentialized by the switch 238. The recording circuit 240 performs a recording process, and the output is recorded on the magnetic sheet 243 by the magnetic heads 241 and 242. Period for recording on the magnetic sheet 243 (two vertical synchronization periods for a frame image, that is, 2V,
Reset switch during 1V for field image)
Leave 252 off.

After the recording on the magnetic sheet 243 is completed, the selector 254 selects the synchronization signal generation circuit 248 again. Then, the image memory 22
The 8,230 stored images are read out in a reduced scale, and a switching signal of the switch 232 is applied to the encoder 234 so that a superimposed signal on the input video signal is applied. This allows the output terminal
The 236 video signal is part of the image of the input video signal,
The recorded image on the magnetic sheet represents the reduced image.

Next, a reproduction mode for reproducing a recording signal of the magnetic sheet 215 will be described. In the reproduction mode, the reproduction output of the magnetic heads 216 and 217 is demodulated by the reproduction circuit 232 and the switches 224 and 226
Are applied to the image memory circuits 228 and 230 via the memory and stored. The reading is performed simultaneously with the storage, and the image memory circuits 228 and 23
The output of 0 is supplied to the output terminal 236 via the switch 232 and the encoder 234. At this time, the selector 254 has selected the synchronization signal generation circuit 248, and the reset switch 252 is in the off state.

When the writing to the image memory circuits 228 and 230 is completed, the selector 254 selects the reference synchronizing signal generation circuit 250, and the image memory circuits 228 and 230 are in the reading state.

FIG. 1A shows a detailed configuration block diagram of the image memory circuit 228. 100 is an A / D converter for digitizing an input analog luminance signal, 102 is a clamp circuit, 104 is K (0 <K
<1) Multiplier, 106 is a multiplier of (1-K) times, 108 is an adder for adding the outputs of the multipliers 104 and 108, 110 is a multiplier 10
A selector for selecting one of the input of 4,108 and the output of the adder 108; a latch circuit 112 for holding predetermined data;
14 is a selector for selecting the output of the selector 110 or the output of the latch circuit 112, and 116 is a dual port having a random access port (hereinafter, referred to as P port) and a serial output port (hereinafter, referred to as S port). The image memory 118 latches the image data output from the selector 114 for three pixels and outputs the latched data in parallel.
This is an SPS conversion circuit that serially outputs image data for three pixels output from 118.

Reference numeral 120 denotes a latch circuit for temporarily storing image data for three pixels output from the S port of the image memory 116, 122 a selector for switching / selecting the output of the latch circuit 120 at a video rate, and 124 a SPS. An adder that adds the image data from the conversion circuit 118 and the image data from the selector 122, 126 is a selector that selects the output of the adder 124 or the output of the selector 122, and 128 is an analog signal that converts the output data of the selector 126 into an analog signal. This is a D / A converter for conversion.

130 is a blanking signal generation circuit that outputs a signal indicating a blanking area, 132 and 134 are latch circuits that hold signals that determine the blanking area, and 136 is an image memory 116.
Address signal for random access port
P address generation circuit for generating a P address signal), 138 an S address generation circuit for generating an address signal for a serial port of the image memory 116 (hereinafter referred to as an S address signal), and 140 a P address generation circuit 136 or S A selector 142 for selecting the output of the address generation circuit 138, and a memory control circuit 142 for controlling the image memory 116.

FIG. 1B shows a detailed configuration block diagram of the image memory circuit 230. The circuits 100 to 110 in FIG. 1B are the same as those in FIG. 1A, except that they are line-sequential color difference signals instead of luminance signals, and the circuits 130 to 142 are the same as those in FIG. 1A. It works. 150 is a color difference signal RY, BY of a line sequential color difference signal.
A color difference discrimination circuit for discriminating, a latch circuit for holding predetermined data, 154, a selector for selecting the output of the latch circuits 152, 154, a selector for selecting the output of the selector 110 or 156, a selector 158 for an image from the selector 158. A latch circuit that stores data at a speed of 1/3 of a normal video rate, 162 (162a, 162b) is an image memory having a dual port like the image memory 116, and 164 is an S of the image memory 162.
A latch circuit for holding two image data output from the port, a selector 166 for selecting two outputs of the latch circuit 164, and a reference numeral 168 for converting the image data output from the P port of the image memory 162 at a normal video rate. Latch circuits that store at 1/3 speed, 170 and 172 are adders that add the output of latch circuit 168 to the output of latch circuit 164, and 174 and 176 are
A selector for selecting the output of the latch circuit 164 or the output of the adders 170 and 172, 178 and 180 are selectors for selecting the outputs of the selectors 174 and 176, and 182 and 184 are D / A converters.

FIG. 3A shows a detailed configuration block diagram of the clamp circuit 102 in FIGS. 1A and 1B and the color difference determination circuit 150 in FIG. 1B. In FIG. 3A, reference numeral 300 denotes an input terminal of image data from the A / D converter 100, reference numeral 302 denotes an adder, and reference numeral 304 denotes a latch circuit for cumulatively adding output data of the adder 302 n times (an integer greater than 1). , 306 is a multiplier for multiplying the output of the latch circuit 304 by 1 / n, 3
08 is a subtractor that subtracts the output data of the multiplier 306 from the input data of the input terminal 300, 310 is a processing circuit that performs processing when an overflow or underflow occurs in the output data of the subtractor 308, and 312 is a processing circuit. An output terminal for outputting the output data of 310, which is connected to the multiplier 108 and the selector 110. In the color difference determination circuit 150, 314 is a latch circuit 304
Latch circuit that holds the output of the
Is a comparison circuit that compares the output of the latch circuit 304 with the output of the latch circuit 314, 318 is a counter that counts the comparison result of the comparison circuit 316, and 320 is a flag that indicates whether or not the count value of the counter 318 has exceeded a predetermined value. This is a latch circuit for notifying the user of the above.

The operation of FIG. 3A will be described. When the image data input to the input terminal 300 is luminance signal data, the latch circuit 304
Is cleared to zero during the horizontal synchronization period. Then, a clock is applied to the latch circuit 304 n times (an integer greater than 1) during the back porch period of the input image data, and the cumulative addition is performed n times. The adder 302 adds the output of the latch circuit 304 to the input image data, and outputs the addition result to the latch circuit 3.
Apply to 04. By this loop, the latch circuit 304 stores data of the back porch period, that is, a value obtained by adding the pedestal level value n times.

Next, the output of the latch circuit 304 is set to 1 / n by the multiplier 306, and the average value of the pedestal level addition n times is obtained. When the output of the multiplier 306 is subtracted from the input image data by the subtractor 308, the image data at the output terminal 312 becomes 00 _HEX
Will be clamped. If the output of the subtractor 308 underflows, the processing circuit 310 forcibly sets 00 _HEX .

In FIG. 3A, even when the input image data is line-sequential color difference signal data, it can be clamped to 00 _HEX in the same manner as the case of the luminance signal. However, since the color difference signal is positive or negative polarity, it must be performed 80 _HEX clamping decides to 80 _HEX and 0V. This means that the input image data is RY / BY (t),
The pedestal level n times added average value Then, to perform 80 _HEX clamping, Which is equivalent to the 00 _HEX clamp plus 80 _HEX .

Normally, the luminance signal and the color difference signal output from the decoder 212 (FIG. 2) do not have a burst signal, but a burst signal having a small amplitude may remain due to leakage in a circuit or the like. In such a case, when the above clamping is performed, the frequency of the clock applied to the latch circuit 304 during the back porch period (burst signal period) is set to 2mf _SC (m is a positive integer, f _SC is the subcarrier frequency), and the cumulative addition is performed. Is 2l times (l is a positive integer) and the coefficient of the multiplier 306 is 1 / 2l
And This makes it possible to cancel the burst signal component. In this case, the present invention can be applied not only to the clamp of the luminance signal and the color difference signal but also to the clamp of the NTSC signal having the burst signal.

The operation of the color difference determination circuit 150 will be described. The signal BY of the line-sequential color difference signal recorded on the magnetic sheet has an offset value, which is higher than the signal RY by that amount.
Therefore, the line-sequential color difference signals R-Y and B-Y can be determined by comparing the added value of n times of the data input during the back porch period with the one before or after 1H during the clamping. This will be described in more detail with reference to FIG. 3B. FIG. 3B (a) is a reproduction line sequential color difference signal input to the input terminal 300,
2B shows a horizontal synchronization signal, FIG. 2C shows a clock for controlling the latch circuit 314, and FIG. 2D shows a clock applied to the counter 318. Note that the counter 318 is cleared to zero during the vertical synchronization period. The output of the latch circuit 304 is determined during the back porch period and is latched by the latch circuit 304 at the timing shown in FIG. 3B (c). The output of the latch circuit 304 is newly determined in the next back porch period, and this output is compared with the output of the latch circuit 314 by the comparison circuit 316. Comparison circuit 31
Based on the result of the comparison in 6, it is controlled whether or not the counter 318 performs counting. This is performed for one field period, and the flag of the latch circuit 320 is determined based on whether the count value of the counter 318 is larger than a predetermined value.

In other words, even if there is noise or dropout, the counter 318 is provided and a majority decision is made within one field period in order to reliably determine the color difference.
It is possible to know whether -Y and BY are each an even raster or an odd raster.

In the configuration of FIG. 2, there are a recording mode in which an input video signal is recorded on a magnetic sheet, and a reproduction mode in which a recorded video signal is reproduced from the magnetic sheet. First, the operation in the recording mode will be described. FIG. 4A shows the flowchart, and FIG.
FIG. 4B shows a time chart. In FIG. 4B, 410 is a field signal output from the synchronization signal generation circuits 248 and 250, 412 is a freeze signal, 414 is a signal indicating a recording period, 416 is a signal indicating a superimposition period of a reduced image, and 418 is a selection signal of the selector 254. This is a signal indicating that the synchronization signal generation circuit 250 has been selected. 420 is a signal indicating a reset state in which the reset switch 252 is on.

The selector 254 selects the synchronization signal generation circuit 248, and the reset switch 252 is turned on. And switch 2
32 selects the input video signal side, and the input video signal of the input terminal 210 is output to the output terminal 236 as it is (S40
0). Next, the image memories 116 and 162 are cleared to predetermined values (S401). In the case of the image memory 116, a predetermined value is latched in the latch circuit 112, and this is selected by the selector 114.
One frame worth of image memory 1 via the PS conversion circuit 118
Write to 16. A value indicating the blanking area is set in the latch circuit 132 so as to satisfy all the normal image areas, and a value indicating the blanking area is set in the latch circuit 134 so as to clear the entire memory space of the image memory 116. Set. While the image memory 116 is being cleared, the latch circuit 134 operates with a blanking signal, and in other cases, the latch circuit 132 operates with a blanking signal.

For the image memory 162, the latch circuit 320 is set to R
−Y signal, and then the latch circuit 15
The selector 156 switches the outputs of the latch circuits 152 and 154 at the timing of the horizontal synchronizing signal, and the selector 158 selects this. Then, one frame worth is taken into the image memory 162 via the latch circuit 160. However, writing to the image memories 162a and 162b is switched for each raster. The blanking area of the blanking signal generation circuit 130 is set so as to clear the entire memory space of the image memory 162, which is the same as the case of the image memory 116. As a result, the image memory 162a is completely cleared to the set value of the latch circuit 152, the image memory 162b is completely cleared to the set value of the latch circuit 154, and the image memory 1
62a is an RY memory, and the image memory 162b is a BY memory.

When an instruction to record an input video signal on a magnetic sheet is input (S402), in FIG. 1A, the input luminance signal is output from the A / D converter 100, the clamp circuit 102, the selectors 110 and 114, and the SP.
One frame is stored in the image memory 1 via the -S conversion circuit 118.
Written to 16. At this time, the operation is performed by the blanking signal from the latch circuit 132 that indicates the image area of the input luminance signal.

The input color difference signal is converted into a line-sequential signal by the switch 214. At this time, it does not matter which of the RY component and the BY component is given first, but since the latch circuit 320 is set to indicate RY at the time of the clearing, in this example, the RY component is set. Need to be first. In FIG. 1B, the line-sequential color difference signal is
2. One frame is written in the image memory 162 via the selectors 110 and 158 and the latch circuit 160. At this time, all the image areas of the input line sequential color difference signals can be stored.
The latch circuit 132 operates with a blanking signal. After the vertical blanking period ends, the first raster image data to be stored is loaded into the image memory 162a, and the second raster image data is stored in the image memory 162a. The data is stored in the memory 162b, and thereafter, the data is alternately captured for each raster. As a result, the RY component of the input line sequential color difference signal data is loaded into the image memory 162a, and the BY component is loaded into the image memory 162b (S403).

Next, the selector 254 selects the output of the synchronization signal generation circuit 250, and turns off the reset switch 252. Then, the image memories 116 and 162 are read out and recorded on the magnetic sheet (S
404). That is, in FIG. 1A, the image data stored as a frame in the image memory 116 is read out from the S port and applied to the D / A converter 128 via the latch circuit 120 and the selectors 122 and 126. When recording the frame image stored in the image memory 116 on the magnetic sheet, the output of the D / A converter 128 may be recorded for one frame. When recording as a field image, the image data is averaged between fields and recorded. The averaging between fields is equivalent to performing filtering between fields.

That is, the signal of the first field of the image data stored as a frame in the image memory 116 is transmitted to the S address generation circuit 138.
Therefore, from the first raster in order from the S port, Y ₀ , Y ₁ , Y ₂ ,
Read out as Y ₃ , Y ₄ , and so on. At the same time, the signals of the second field are sent by the P address generation circuit 136 from the first raster in order from the P port to Y ₀ ′, Y ₁ ′, Y ₂ ′, Y ₃ ′,
Read it out as Y ₄ ′, .... The selector 126 selects the output of the adder 124. This allows the D / A converter 128
Output is (Y ₀ + Y ₀ ′) / 2, (Y ₁ + Y ₁ ′) / 2, (Y ₂ + Y ₂ ′)
/ 2, (Y ₃ + Y ₃ ′) / 2, (Y ₄ + Y ₄ ′) / 2, ..., which is recorded as one field.

The color difference signal is as follows. In FIG. 1B, the image data stored in the image memory 162 in frames are simultaneously rasterized from the S port by two rasters, RY ₀ , RY ₀ , RY ₂ , RY ₂ , RY ₄ , RY ₄ , RY ₆ , RY ₆ ,. _{BY 1, BY 1, BY 3} , BY 3, BY 5, BY 5, BY 7, BY 7, reading and so on .... Latch circuit 164 and selector 174
The D / A converters 182, 184 are always R-Y, B
-Output the Y signal.

When recording the image stored in the image memory 162 as a frame image on the magnetic sheet, the switch 238 is alternately provided for each raster from the component (RY) indicated by the latch circuit 320.
By selecting in (Fig. 2), RY ₀ , BY ₁ , RY ₂ , B
_{Y 3, RY 4, BY 5} , RY 6, BY 7, to line sequence so on .... This is recorded on a magnetic sheet for one frame. At this time, the data may also be read from the P port at the same time and the synchronization described later may be performed.

On the other hand, in the case of field recording, the image data is averaged between the fields and recorded. That is,
RY ₀ , RY ₀ , RY ₂ , RY ₂ , RY ₄ , RY ₄ , RY ₆ , RY ₆ , ... One field of the image data recorded in frames in the image memory 162 from the S port at the same time by two rasters at a time. ... BY ₁ , BY ₁ , BY ₃ , BY ₃ , BY ₅ , BY ₅ , BY ₇ , BY ₇ , ... are read out. At the same time, the other field
The RY and BY rasters are read alternately from the port as RY ₀ ′, BY ₁ ′, RY ₂ ′, BY ₃ ′, RY ₄ ′, BY ₅ ′, .... Both the selectors 174 and 176 switch the input signal for each raster, and the selectors 178 and 180 switch so that the D / A converters 182 and 184 always output the RY and BY signals, respectively. As a result, the output of the D / A converter 182 is (RY ₀ + RY ₀ ′) / 2, RY ₀ , (RY ₂ + RY ₂ ′) / 2, RY ₂ , and (RY ₄
+ RY ₄ ′) / 2, RY ₄ , ..., and the output of D / A converter 184 is B
Y ₁ , (BY ₁ + BY ₁ ′) / 2, BY ₃ (BY ₃ + BY ₃ ′) / 2, BY ₅ , (BY
₅ + BY ₅ ′) / 2, ...

Here, from the component (RY) indicated by the latch circuit 320, 1
When the switch 238 is alternately switched for each raster, a raster in which averaging is always performed is obtained, and the output of the switch 238 is (RY ₀ + RY ₀ ') / 2, (BY ₁ + BY ₁ ') / 2, (RY ₂ + R
Y ₂ ′) / 2, (BY ₃ ＋ BY ₃ ′) / 2, (RY ₄ ＋ RY ₄ ′) / 2, BY ₅ ＋ BY
₅ ′) / 2 ……. This is recorded on a magnetic sheet for one field.

Next, the selector 254 selects the output of the synchronization signal generation circuit 248 again, and turns on the reset switch 152. Then, the images stored in the image memories 116 and 162 are read out in a reduced scale and superimposed on the input video signal (S405). That is, in FIG. 1A, the image data stored in the frame in the image memory 116 is read out from the S port, and the data for three pixels is latched.
Latch. The selector 122 selects only one pixel among them. By reading from the S port at the video rate, the image stored in the image memory 116 can be reduced to 1/3 in the horizontal direction.
become. Further, by making the vertical address signal by the S address generation circuit 138 point to the address for every three rasters, the image stored in the image memory 116 becomes 1/3 in the vertical direction.

In FIG. 1B, two rasters of RY and BY are simultaneously read out from the S port of the image data stored in the frame in the image memory 162. Since the color difference signal has a narrow band, it is stored at a speed of 1/3 of the normal video rate. Therefore, when reading at the normal video rate, the image stored in the image memory 162 is 1 horizontal. / 3. Further, by pointing the vertical address signal by the S address generation circuit 138 to the address every 3 steps, 2 rasters at a time from the S port, RY ₀ , RY ₂ , RY ₆ , RY ₈ , RY ₁₂ , RY ₁₄ , ... BY ₁ , BY ₃ , BY ₇ , BY ₉ , BY ₁₃ , BY ₁₅ , ... are read out, and the image stored in the image memory 162 becomes 1/3 in the vertical direction.

In FIG. 5A, if an area other than the image in the entire space of the image memories 116 and 162 is read in an overlapping manner both in the horizontal direction and the vertical direction, a frame is easily formed on the image reduced to 1/3 × 1/3. be able to. That, S address generating circuit 138 is typically a horizontal address, although output x ₀ → x _1, where x ₁ → x ₂ (=
x ₀ ) → x ₁ → x ₂ and the vertical address is usually y ₀ →
It is y ₁ , but here it is output as y ₁ → y ₂ (= y ₀ ) → y ₁ → y ₂ . As a result, a frame can be provided as shown in FIG. 5B. When a reduced image is displayed, the switch 232 is connected to the output side of the image memory circuits 228 and 230, and otherwise, the switch 232 is connected to the input video signal (decoder 212).
As shown in FIG. C, a reduced image can be superimposed on an input image and displayed.

The control signal of the switch 232 becomes equal to the blanking signal of the blanking signal generation circuit 130, and the superimposed position of the reduced image can be moved by changing the blanking signal. Here, a new value is set again in the latch circuit 134, and the latch circuit 134 is operated by the blanking signal.

Next, the recording heads 241 and 242 are moved (S406), and the apparatus enters a standby state until the next recording command is input. Thereafter, the above operation is repeated.

FIG. 4A is a time chart in the case of recording a frame of an input video signal on a magnetic sheet.
This shows a case where clearing of 6,162 and recording on the magnetic sheet are performed twice.

Next, the reproduction mode will be described. FIG. 6A shows the flowchart, and FIGS. 6B and 6C show the time charts. 610 and 612 are field signals generated by the synchronization signal generation circuits 248 and 250, 614 is a signal indicating a color difference determination period of a reproduction line sequential color difference signal, 616 is a freeze signal, and 618 is a selector.
A selection control signal 254 is a signal indicating that the synchronization signal generation circuit 250 has been selected, and a signal 620 is a signal indicating the state of the reset switch 252 (reset when turned on).

Since the sync signal generation circuit 248 is synchronized with the horizontal sync signal of the reproduced video signal reproduced from the magnetic sheet 215 and reset by the vertical sync signal, it outputs the same sync signal as the sync signal of the reproduced video signal. A motor (not shown) for rotating the magnetic sheet 215 is provided with a reference synchronizing signal generation circuit.
Since the rotation is synchronized with the vertical synchronization signal output from 250 and the reset switch 252 is off, the magnetic sheet 215
The vertical synchronizing signal of the reproduced video signal reproduced from is synchronized with the vertical synchronizing signal output from the reference synchronizing signal generation circuit 250. In the case of a field image, the fields match every field, but when the reproduced image is a frame image, there is a possibility that the fields do not match in both synchronization signal generating circuits 248 and 250. In the case where the signal recorded on the magnetic sheet 215 is a frame, when the various synchronization signals generated by the synchronization signal generation circuit 248 and the various synchronization signals generated by the reference synchronization signal generation circuit 250 are switched, the above-mentioned synchronization signals are used. As described above, when the fields do not match, a skew will occur at the time of switching the synchronizing signal.

Therefore, first, the fields are matched (S600). That is,
Frame reproduction is performed by alternately reproducing the video signal recorded as two fields on two tracks of the magnetic sheet 215 by the switch 218. If the fields do not match as described above, it is detected by the comparison circuit 256. Then, this alternate reproduction is stopped for a period of 1V. By stopping the switching of the switch 218 for a period of 1 V, the mutual fields are matched. Thereafter, the color difference determination circuit 150
Is determined for each of the two fields, and this is stored in the latch circuit 320 (S601). here,
The selector 254 selects the synchronization signal generation circuit 248, turns off the reset switch 252, and freezes the reproduced video signal.

When the signal recorded on the magnetic sheet 215 is a field image, the reproduced video signal is always in one field, whereas the reference synchronization signal generation circuit 250 uses the reset switch 2
Since the sync signal of the frame picture is generated when 52 is off, the fields match each other, and when the sync signals of the sync signal generating circuits 248 and 250 are switched when they do not match, skew occurs. Therefore, the fields are adjusted first (S600). That is, when the comparison circuit 256 detects that the fields do not match as described above, the fields can be matched by controlling the image memory circuits 228 and 230 and waiting for a period of 1V. Thereafter, in the next 1 V period, the determination is performed by the color difference determination circuit 150, and the determination result is stored in the latch circuit 320. At this time, the fields do not match (S60
1). Here, the selector 254 selects the synchronization signal generation circuit 248, and freezes the reproduced video signal in the next 1V period.
At this time, the fields match.

Now, in FIG. 1A, the reproduced luminance signal is an A / D converter 10
0, clamp circuit 102, selectors 110 and 114 and SPS
Through the conversion circuit 118, one frame or one field is transferred to the image memory 116 from the P port through Y ₀ , Y ₁ , Y ₂ , Y ₃ ,
Written as Y ₄ , Y ₅ , and so on. This signal is simultaneously read out from the S port in the order of Y ₀ , Y ₀ , Y ₁ , Y ₂ , Y ₃ , Y ₄ , ..., and the selector 126, the D / A converter 128, the switch 232 and the encoder. Output terminal through 234
It is output to 236. On the other hand, the output of the selector 122 is the selector
It is also applied to 110, that is, the image data one raster before the input reproduction luminance signal, and when the reproduction video signal has a dropout, the selector 110 keeps the 1 Select image data before rasterization and perform dropout compensation.

In FIG. 1B, a reproduction line sequential color difference signal is supplied to an A / D converter 10.
0, clamp circuit 102, selectors 110 and 158, and latch circuit 1
RY ₀ , BY ₁ , RY ₂ , BY ₃ , R in the image memory 162 via 60
It is assumed that input is made in order from the RY component, such as Y ₄ , BY ₅ , RY ₆ , BY ₇ , .... The image data for one frame or one field is alternately loaded into the image memories 162a and 162b from the P port for each raster. 2 rasters at a time from the S port, RY ₀ , RY ₀ , RY ₀ , RY ₀ , RY ₂ , RY ₂ , RY ₄ , RY ₄ , ... BY ₁ , BY ₁ , BY ₁ , BY ₁ , BY ₃ , BY Read out as ₃ , BY ₅ , BY ₅ , .... The image data is processed by selectors 174, 176, 178, and 180 so that D / A converters 182 and 184 always output R-Y and BY components, respectively.
It is distributed to converters 182 and 184. On the other hand, the selector 166
RY ₀ , BY ₁ , RY ₀ , BY ₁ , RY ₂ , BY ₃ , RY ₄ , BY ₅ , RY ₆ , BY ₇ ,
.. is selected in this order, and this output is also applied to the selector 110. This means that 2 of the input reproduction line sequential color difference signals
This is the image data before rasterization, and if there is a dropout in the playback video signal, the selector 110
Selects the image data two rasters before and performs dropout compensation (S602).

Next, in FIG. 1A, the reproduction luminance signal is continuously input to the A / D converter 100, and the selector 110 selects the output of the adder 108 and freezes this for one frame or field in the image memory 116. To do. At the same time, from the S port, the same field as the reproduced luminance signal field is changed to Y ₀ , Y ₁ , Y ₂ ,
_{Y 3, Y 4, Y 5} , ...... read, and multiplied by the multiplier 104 by a factor K (0 <K <1) to the data, the coefficient in the multiplier 106 to the reproduced luminance signal (1-K) The product obtained by the multiplication is added by the adder 108. At this time, if there is a dropout in the reproduction luminance signal, the selector 110 selects the output side of the selector 122 during that period and performs dropout compensation.

In FIG. 1B, a reproduction line sequential color difference signal is successively input to the A / D converter 100, and the selector 110 selects the output of the adder 108, and freezes it for one frame or one field in the image memory 162. I do. At this time, the same field as the field of the reproduction line sequential color difference signal from the S port is simultaneously rasterized by two rasters, RY ₀ , RY ₀ , RY ₂ , RY ₂ , RY ₄ , RY ₄ , RY ₆ , RY ₆ , ... BY Read as ₁ , BY ₁ , BY ₃ , BY ₃ , BY ₅ , BY ₅ , BY ₇ , BY ₇ , .... The selector 166 selects this and outputs it as RY ₀ , BY ₁ , RY ₂ , BY ₃ , RY ₄ , BY ₅ , RY ₆ , BY ₇ , .... The coefficient K (0 <0
An adder 108 adds a product obtained by multiplying K <1) and a product obtained by multiplying the reproduction line sequential color difference signal by the coefficient (1-K) at the multiplier 106. When there is a dropout in the reproduction line sequential color difference signal, during that period, the selector 110 selects the output side of the selector 166 and performs dropout compensation.

By performing the above operation for a period of several volts, the magnetic sheet 21
The image data of the same still image reproduced from 5 is added several times. Random noise can be reduced by the addition (S603). If the playback video signal is a frame, the above operation is performed in units of frames. If the playback video signal is a field, the field of the playback video signal and the synchronization signal generation circuit 25
When the 0 field matches, perform the above operation,
When they do not match, the image memories 116 and 162 are read out by performing inter-field interpolation described later.

FIG. 6B is a time chart when the reproduced video signal is a frame.
The case where noise reduction is performed over a frame is shown.
Figure 6C shows the time when the playback video signal is in the field.
5 is a chart showing a case where noise reduction is not performed and a case where noise reduction is performed over four fields.

Next, data stored in the image memories 228 and 230 is read (S
604). In the case of a luminance signal, in FIG. 1A, stored data is read from the S port of the image memory 116 in accordance with the address signal from the S address generation circuit 138. This read signal is applied to the D / A converter 128 via the selectors 122 and 126. If the image stored in the image memory 116 is a frame image, it may be read out alternately one field at a time. In the case of a field image, a signal read as it is is used for one field, and a signal obtained by performing inter-field interpolation is used for the other field. That is, when an image stored in the odd field of the image memory 116 is used, when output as an odd field signal, Y ₀ , Y ₁ ,
_{Y 2, Y 3, Y 4} , Y 5, Y 6, read in normal raster order and so ...., is output via the selector 122, 126 and the D / A converter 128. When outputting as an even field signal, Y ₀ , Y ₁ , Y ₂ , Y ₃ , from the S port of the image memory 116,
At the same time as reading Y ₄ , Y ₅ , Y ₆ , ... At the same time, reading from the P port is Y ₁ , Y ₂ , Y ₃ , Y ₄ , Y ₅ , Y ₆ ,. This S port output and P port output are added by an adder 124
Is added and averaged, and the selector 126 selects the output of the adder 124. As a result, the output of the D / A converter 128 is Y ₀ , Y ₁ , Y ₂ , Y ₃ , Y ₄ , Y ₅ , Y ₆ , ... In the odd field and (Y ₀ + Y ₁ ) / 2, (Y ₁ + Y ₂ ) / 2, (Y ₂ + Y ₃ )
Inter-field interpolation values such as / 2, (Y ₃ + Y ₄ ) / 2, (Y ₄ + Y ₅ ) / 2 ,.

In the case of using the signal stored in the even field of the image memory 116, when outputting as an even field signal, Y ₀ , Y ₁ ,
When reading out in the normal raster order as Y ₂ , Y ₃ , Y ₄ , Y ₅ , Y ₆ , ... And outputting as an odd field signal, Y ₀ , Y ₁ , Y ₂ , from the S port of the image memory 116. Y ₃ ,
At the same time as reading Y ₄ , Y ₅ , Y ₆ , ..., at the same time as normal raster order from the P port, Y ₀ , Y ₀ , Y ₁ , Y ₂ , Y ₃ , Y ₄ , Y ₅ , ... To read the data one raster before. The S port output and the P port output are added and averaged by an adder 124, and a selector 126 selects an output of the adder 124. As a result, the output of the D / A converter 128 is (Y ₀
+ Y ₀ ) / 2, (Y ₀ + Y ₁ ) / 2, (Y ₁ + Y ₂ ) / 2, (Y ₂ + Y ₃ ) / 2,
Inter-field interpolated values such as (Y ₃ + Y ₄ ) / 2, (Y ₄ + Y ₅ ) / 2, and so on are Y ₀ , Y ₁ , Y ₂ ,
Y ₃ , Y ₄ , Y ₅ , Y ₆ , and so on.

The color difference signal is as follows. Image memory circuit
Since the input signal to 230 is a line-sequential color difference signal, it is necessary to perform line synchronization when outputting the stored data. That is, in FIG. 1B, the line-sequential color difference signals input to the image memory 162 are RY ₀ , RY ₁ , RY ₂ , RY ₃ , RY for each raster.
₄ , RY ₅ , RY ₆ , RY ₇ , ... When starting from the RY components, the RY components RY ₀ , R are stored in the image memory 162a.
Y ₂ , RY ₄ , RY ₆ , ... are stored, and B is stored in the image memory 162b.
-Y component _{BY 1, BY 3, BY 5} , BY 7, ...... is stored, the latch circuit 320 of the color difference discriminating circuit 150, the first raster is in a state indicative of a R-Y component. Then, the data stored in the image memory 152 is simultaneously output from the S port by 2 rasters at a time, RY ₀ , RY ₀ , RY ₂ , RY ₂ , RY ₄ , RY ₄ , RY ₆ , RY ₆ , ... BY ₁ , BY ₁ , BY. ₃ , BY ₃ , BY ₅ , BY ₅ , BY ₇ , BY ₇ , ... are read out. R from the P port at the same time
-Y, BY ₁ the BY raster _{alternately, RY 2, BY 1, RY} 4, BY 3,
Read out as RY ₆ , BY ₅ , and so on.

The selectors 174 and 176 both switch the input signal for each raster, and the selectors 178 and 180 switch so that the D / A converters 182 and 184 always output the RY and BY signals, respectively. As a result, the D / A converter 182 outputs RY ₀ , (RY ₀ + RY ₂ ) / 2, RY ₂ , (R
_{Y 2 + RY 4) / 2} , RY 4, (RY 4 + RY 6) / 2, and outputs a ......, D / A
The converter 184 has (BY ₁ + BY ₁ ) / 2, BY ₁ , (BY ₁ + BY ₃ ) / 2, B
_{Y 3, (BY 3 + BY} 5) / 2, BY 5, outputs ..., line synchronizing the chrominance signal is formed.

When the line-sequential color difference signal input to the image memory circuit 230 starts with the BY component, the BY memory BY ₀ , BY ₂ , BY ₄ , BY ₆ , ... Is stored in the image memory 162a. The RY components RY ₁ , RY ₃ , RY ₅ , RY ₇ , ... Are stored in the image memory 162b.
Is stored in the latch circuit 320 of the color difference determination circuit 150,
The raster is in a state indicating that it is a BY component. Then, the data stored in the image memory 162 is simultaneously output from the S port by 2 rasters at a time, BY ₀ , BY ₀ , BY ₂ , BY ₂ , BY ₄ , BY ₄ , BY ₆ , BY ₆ , ... RY ₁ , RY ₁ , RY. _{3, RY 3, RY 5,} RY 5, RY 7, RY 7, read and so on ..., at the same time also from the P port, R-
RY ₁ , BY ₂ , RY ₁ , BY ₄ , RY ₃ ,
BY ₆ , RY ₅ , ... and so on. Selector 17
By switching from 4 to 180, the D / A converter 182 becomes (RY ₁ + RY ₁ ) / 2, R
_{Y 1, (RY 1 + RY} 3) / 2, RY 3, (RY 3 + RY 5) / 2, RY 5, outputs ......, D / A converter 184 _{BY 0, (BY 0 + BY} 2) / 2, BY ₂ , (B
Outputs Y ₂ + BY ₄ ) / 2, BY ₄ , (BY ₄ + BY ₆ ) / 2, ....

When the image stored in the image memory 162 is a frame image, the above operation may be performed in each field. In the case of a field image, the above operation is performed twice consecutively in one field (S604).

Next, the reproducing heads 216 and 217 are moved (S605) to enter a standby state, and thereafter, the above operation is repeated.

In the above-mentioned reproduction mode, the latch circuit 132 indicating the blanking area operates, and the image areas of these reproduced video signals are all satisfied.

In the playback mode, the playback image is reduced to reduce the image memory 11
The operation of recording at 6,162 will be described. The flowchart is shown in FIG. 7A. The time chart at this time is 6C
This is the same as the case where noise reduction is not performed when the reproduced video signal is a field.

First, the image memories 116 and 162 are cleared to predetermined values (S70
0). Next, field matching is performed between the reproduced video signal of the field image and the reference synchronization signal generation circuit 250 (S70).
1) In the 1V period, the color difference determination circuit 150 makes a determination (S70)
2). Since the details of this part are the same as the description, the description is omitted. Next, the selector 254 selects the synchronization signal generation circuit 248, reduces the image of the reproduced video signal in the next 1V period, and writes it in the image memories 116 and 162 (S703). That is, in FIG. 1B, the reproduction line sequential color difference signals are RY ₀ , BY ₁ ,
RY ₂ , BY ₃ , RY ₄ , BY ₅ , RY ₆ , BY ₇ , ..., R-
It is assumed that it starts from the Y component. For example, when this is reduced to a 1/5 × 1/5 field image and stored in the image memory 162, the P address generation circuit 136 is used to multiply the horizontal direction by 1/5.
The clock for horizontal address signal generation is divided by 1/5,
In order to multiply the vertical direction by 1/5, the horizontal synchronizing signal for generating the vertical address signal of the P address generating circuit 136 is divided by 1/5. In other words, the reproduction line sequential color difference signal is sampled at a ratio of 1 raster to 5 rasters and alternately from the RY component, and other data is thinned out. For example, RY ₀ , BY ₁ , RY ₂ , B
Y ₃ , RY ₄ , BY ₅ , RY ₆ , BY ₇ , RY ₈ , BY ₉ , RY ₁₀ , BY ₁₁ , ......
From RY ₀ , BY ₅ , RY ₁₀ , ... or
Sampling of RY ₀ , BY ₁ , RY ₁₀ , BY ₁₁ , ... Is performed. The decimated raster is always captured in the lowest raster area of the image memory 162 memory space for dropout compensation. That is, in the case of RY, the image memory
In the case of 162a and BY, they are taken into the lowest raster area of the image memory 162b. Simultaneously with this writing, the lowest raster area of the memory space of the image memory 162 is always read from the S port by 2 rasters at a time, and is alternately selected by the selector 166 to be used for dropout compensation of the reproduced video signal in the same manner as described above. .

As described above, a 1/5 × 1/5 reduced image from the line-sequential color difference signal of the field image is stored in the image memory as a field image.
162 can be stored.

It is also reduced to 1/5 x 1/5 frame image
In the case where the data is stored in the 162, it is the same as described above to multiply by 1/5 in the horizontal direction. In order to multiply by 1/5 in the vertical direction, the horizontal synchronizing signal for generating the vertical address signal of the P address
Divide by / 5 frequency division or a frequency division rate equivalent to this. In other words, sampling is performed at a rate of 2 rasters to 5 rasters from the reproduction line sequential color difference signal and 2 rasters at a time from the RY component. For example, sample RY ₀ , RY ₂ , BY ₅ , BY ₇ , RY ₁₀ , RY ₁₂ , ... Or sample RY ₀ , RY ₂ , BY ₇ , BY ₉ , RY ₁₀ , RY ₁₂ , .... . Then, the fields are alternately switched one raster at a time. In the former case, RY ₀ , BY ₅ , RY ₁₀ , ... Are stored in the odd field of the image memory 162, and RY ₂ , BY ₇ , RY ₁₂ ,. The decimated raster is stored in the lowest raster area of the memory space of the image memory 162, and is read out from the S port and used for dropout compensation of the reproduced video signal as described above.

As described above, a reduced image of 1/5 × 1/5 is reproduced as a frame image from the reproduced line-sequential color difference signals of the field image as an image memory 16.
2 can be stored.

By changing the initial value of the P address generating circuit 136, the reduced image can be arranged and stored at an arbitrary position in the memory space of the image memory 162.
Since 162 is apparently a line-sequential color difference memory, it must be fetched from the R-Y component raster of the image memory 162.

Similarly, the P address generation circuit
1/5 clock to generate 136 horizontal address signals
By dividing the frequency, the horizontal direction is reduced, and in the vertical direction, the raster of the luminance signal corresponding to the raster of the reproduction line sequential color difference signal fetched into the image memory 162 may be fetched into the image memory 116. Dropout compensation can be performed similarly. Here, a new value is set again in the latch circuit 134 so as to store an area smaller than the image area of the reproduced video signal determined by the latch circuit 132,
The reduced image is stored in the image memory by the blanking signal.

Reproduction line sequential color difference signal is BY ₀ , RY ₁ , BY ₂ , R for each raster
_{Y 3, BY 4, RY 5} , BY 6, RY 7, BY 8, and so ...... B-
If the Y components are sequentially input, the blanking area is shifted by 1 raster and set, and RY ₁ , BY ₂ , RY ₃ , BY ₄ , R
The above operation is performed assuming that Y ₅ , BY ₆ , RY ₇ , BY ₈ , ... And RY components are sequentially input.

Next, the selector 254 selects the reference synchronization signal generation circuit 250, and reads out the image memories 116 and 162 (S704). At this time, the latch circuit 132 operates according to a blanking signal. Then, by feeding the reproduction track of the magnetic sheet 215 (S705) and storing the reduced image in the same manner, 25 5 × 5 field images or frame images as shown in FIG. 7B can be obtained.

Note that the same can be applied to other reduction ratios.

〔The invention's effect〕

As can be easily understood from the above description, according to the present invention, an image memory is used in place of the delay line or the line memory, and the line synchronization of the line-sequential color difference signals is realized by digital processing. All the drawbacks can be eliminated. In addition, since a gate array can be provided, the circuit scale, cost, and the like can be significantly reduced.

[Brief description of the drawings]

FIG. 1A is a configuration block diagram of an image memory circuit for a luminance signal,
FIG. 1B is a block diagram showing a configuration of an image memory circuit for line-sequential color difference signals, FIG. 2 is a block diagram showing a system configuration of an embodiment of the present invention, and FIG. 3A is a clamp circuit 102 and a color difference circuit shown in FIGS. FIG. 3B is a time chart of the color difference determination circuit 150, FIG. 4A is a flowchart of the recording mode, and FIG. 4B is a time chart of the recording mode.
Charts, FIGS. 5A, 5B and 5C are illustrations for displaying a picture-in-picture, FIG. 6A is a flowchart of a playback mode, FIGS. 6B and 6C are time charts of a playback mode, FIG. FIG. 7 is a flowchart of a multi-screen freeze, FIG. 7B is an explanatory diagram of a 5 × 5 multi-screen, and FIGS. 8A and 8B are block diagrams of a conventional example. 116 image memory 118 SPS conversion circuit 130
…… Blanking signal generation circuit, 132, 134… Latch circuit, 136… P address generation circuit, 138… S address generation circuit, 150… Color difference discrimination circuit, 162 (162a, 162b)…
Image memory, 210: External input terminal, 215: Magnetic sheet for reproduction, 228, 230 Image memory circuit, 236: Output terminal, 243: Magnetic sheet for recording, 246: Synchronous separation circuit,
248 synchronization signal generation circuit, 250 reference synchronization signal generation circuit, 252 reset switch

Claims (1)

(57) [Claims] 1. An image memory having at least three output ports, into which line-sequential color difference signals are written, and a color difference signal for three lines adjacent to each other are read from the three output ports. An address control means for controlling a read address, and an average for averaging outputs of two output ports other than the output port reading the color difference signal of the line located in the center of the three adjacent lines among the three output ports. And a line-simultaneous color difference signal is obtained from the output from the output port reading the color difference signal of the line located at the center of the three adjacent lines and the output of the averaging means. An image processing device characterized by: