JP2635693B2 - Luminance signal / color signal separation circuit - Google Patents

Luminance signal / color signal separation circuit

Info

Publication number
JP2635693B2
JP2635693B2 JP15446488A JP15446488A JP2635693B2 JP 2635693 B2 JP2635693 B2 JP 2635693B2 JP 15446488 A JP15446488 A JP 15446488A JP 15446488 A JP15446488 A JP 15446488A JP 2635693 B2 JP2635693 B2 JP 2635693B2
Authority
JP
Japan
Prior art keywords
signal
output
band
delay
intermediate value
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Lifetime
Application number
JP15446488A
Other languages
Japanese (ja)
Other versions
JPH01319387A (en
Inventor
俊光 梅沢
賢一 永井
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Toshiba Corp
Original Assignee
Toshiba Corp
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Toshiba Corp filed Critical Toshiba Corp
Priority to JP15446488A priority Critical patent/JP2635693B2/en
Publication of JPH01319387A publication Critical patent/JPH01319387A/en
Application granted granted Critical
Publication of JP2635693B2 publication Critical patent/JP2635693B2/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Landscapes

  • Processing Of Color Television Signals (AREA)

Description

【発明の詳細な説明】 [発明の目的] (産業上の利用分野) 本発明は例えばカラーテレビジョン受像機において複
合映像信号より輝度信号及び色信号を効果的に分離する
ための輝度信号・色信号分離回路に関する。DETAILED DESCRIPTION OF THE INVENTION [Object of the Invention] (Industrial application field) The present invention relates to a luminance signal / color for effectively separating a luminance signal and a chrominance signal from a composite video signal in, for example, a color television receiver. The present invention relates to a signal separation circuit.

(従来の技術) NTSC方式では、赤,緑,青の原色信号を画面の明るさ
を現わす輝度信号と、色相と彩度の情報をもった色信号
に作りなおして伝送する。正しい色を再現するには、す
でに白黒受像機のために輝度信号を送っているので、カ
ラー受像機のためには、輝度信号と加え合わせたときに
原色信号になる色信号を送る必要がある。(Prior Art) In the NTSC system, red, green, and blue primary color signals are re-created as a luminance signal representing the brightness of a screen and a color signal having hue and saturation information, and transmitted. To reproduce the correct color, a luminance signal has already been sent for a black and white receiver, so for a color receiver, it is necessary to send a color signal that becomes a primary color signal when added to the luminance signal .

色信号をのせるための色副搬送波と輝度信号との関係
は第9図に示すように選んで、信号相互間で妨害が生じ
ないようにしている。すなわち、0〜4.2MHzの輝度信号
(Y信号)と輝度信号の高域相当部に3.579545MHzを副
搬送波とした色信号(C信号)が挿入されている。従っ
て、カラー受像機で放送信号を再生するためには、輝度
信号と色信号を分離する必要がある。輝度信号と色信号
の分離方法には通常次のような2つの方法が用いられて
いる。The relationship between the chrominance subcarrier and the luminance signal for carrying the chrominance signal is selected as shown in FIG. 9 so that no interference occurs between the signals. That is, a luminance signal (Y signal) of 0 to 4.2 MHz and a chrominance signal (C signal) having 3.579545 MHz as a subcarrier are inserted into a portion corresponding to the high frequency of the luminance signal. Therefore, in order to reproduce a broadcast signal with a color receiver, it is necessary to separate a luminance signal and a chrominance signal. Generally, the following two methods are used to separate the luminance signal and the chrominance signal.

第1の方法はトラップを使用する方法であって、複合
映像信号を3.58MHzのトラップを通過させることによ
り、色信号を吸収して輝度信号のみを取り出し、色信号
については複合映像信号を3.58MHz±0.5MHzの帯域ィル
タを通過させることにより取り出す。The first method is a method using a trap. By passing a composite video signal through a trap of 3.58 MHz, a color signal is absorbed to extract only a luminance signal. It is extracted by passing through a ± 0.5 MHz band filter.

第2の方法は、くし形フィルタによる方法である。NT
SC方式では色副搬送波の位相が1水平期間(1H)ごとに
反転(逆相)していることを利用するものである。第10
図はくし形フィルタの構成を示している。第11図は第10
図中の(a)〜(d)各端子それぞれの波形を示す。但
し、第11図は1Hごとに複合映像信号をY信号とC信号の
組合せにおいて示し、同期信号は省略してある。The second method is a method using a comb filter. NT
The SC method utilizes that the phase of the color subcarrier is inverted (reverse phase) every one horizontal period (1H). Tenth
The figure shows the configuration of the comb filter. Figure 11 shows the 10th
The waveforms at the respective terminals (a) to (d) in the figure are shown. However, FIG. 11 shows a composite video signal for each 1H in a combination of a Y signal and a C signal, and the synchronization signal is omitted.

第10図において、符号1複合は映像信号の入力端子で
あり、端子1に入力された複合映像信号は1H遅延回路2
にて1H遅延されて加算回路3に加えられる。加算回路3
では遅延前の信号と1H遅延された信号を加算する。また
5は減算回路、7及び8はゲイン1/2の減衰器である。
そして、出力端子は4及び6にはそれぞれ輝度信号及び
色信号が得られる。In FIG. 10, reference numeral 1 denotes a composite video signal input terminal, and the composite video signal input to the terminal 1 is a 1H delay circuit 2
And is added to the addition circuit 3 after being delayed by 1H. Addition circuit 3
Then, the signal before the delay and the signal delayed by 1H are added. Reference numeral 5 denotes a subtraction circuit, and reference numerals 7 and 8 denote attenuators having a gain of 1/2.
The output terminals 4 and 6 obtain a luminance signal and a chrominance signal, respectively.

しかしながら、複合映像信号より輝度信号と色信号を
分離するのに、上記トラップによる第1の方法を用いる
と、色信号を除くと同時に輝度信号の高域成分(具体的
には輝度信号の3.58MHz成分)をも除去してしまうた
め、細かな画像がぼけたりして画質の低下を招くという
欠点がある。However, when the first method using the above trap is used to separate the luminance signal and the chrominance signal from the composite video signal, the high-frequency component of the luminance signal (specifically, the 3.58 MHz Component) is also removed, so that there is a disadvantage that a fine image is blurred and the image quality is reduced.

また、上記くし形フィルタによる第2の方法を用いる
と、第12図(a)に示すように複合映像信号の1H前後に
相関のない部分がある場合には、(a)に示す映像信号
と同図(b)に示す1H遅延された映像信号との間に、相
関がある部分については加算後、同図(c)におけるA
部分のように輝度信号の高域成分(この成分は色信号の
ように1Hごとに逆相とはなっていない)を除去すること
なく、色号を除去することができる。しかし、1H前後で
相関がない部分B,Cについては輝度信号中に色信号成分
が残ってしまい、画像のエッジ部にドットが生ずる不都
合がある。また輝度信号自身もB,C部ではその振幅がA
部に比べ1/2となり再現画像は垂直方向に広がりを持ち
なまった画像となってしまう不都合がある。同図(d)
は減算による色信号を示しており、やはりB,C部では色
信号中に輝度信号成分が残ってしまい、画像のエッジ部
にクロスカラーが生じる不都合があり、また色信号自身
も輝度信号と同様に再現画像は垂直方向に広がりを持ち
なまった画像となってしまう不具合がある。When the second method using the above-described comb filter is used, when there is an uncorrelated portion around 1H of the composite video signal as shown in FIG. 12A, the video signal shown in FIG. A portion having a correlation with the video signal delayed by 1H shown in FIG.
The color signal can be removed without removing the high frequency component of the luminance signal (this component does not have an opposite phase every 1H like the color signal) as in the part. However, in the portions B and C where there is no correlation around 1H, color signal components remain in the luminance signal, and there is a disadvantage that dots are formed at the edge portion of the image. The luminance signal itself has an amplitude of A in the B and C sections.
There is an inconvenience that the reproduced image becomes a half-spread image in the vertical direction. Figure (d)
Indicates a color signal obtained by subtraction.Also, in the B and C portions, a luminance signal component remains in the color signal, there is a disadvantage that a cross color occurs at an edge portion of the image, and the color signal itself is similar to the luminance signal. However, there is a problem that the reproduced image becomes an image having a spread in the vertical direction.

(発明が解決しようとする課題) 上記の如く、従来の回路では、複合映像信号から輝度
信号を分離する時に、輝度信号の高域成分が除かれてし
まったり、複合映像信号の1H前後に相関のない部分があ
る場合に分離した輝度信号中及び色信号中にそれぞれ色
信号成分及び輝度信号成分が残ってしまったりするとい
う問題があった。(Problems to be Solved by the Invention) As described above, in the conventional circuit, when a luminance signal is separated from a composite video signal, a high-frequency component of the luminance signal is removed or a correlation is generated around 1H of the composite video signal. In the case where there is no portion, the color signal component and the luminance signal component remain in the separated luminance signal and color signal, respectively.

本発明は上述した点にかんがみ、複合映像信号の1H前
後に相関のない部分がある場合でも、複合映像信号より
輝度信号と色信号を効果的に分離することが可能な輝度
信号・色信号分離回路を提供することにある。In view of the above, the present invention provides a luminance signal / chrominance signal separation that can effectively separate a luminance signal and a chrominance signal from a composite video signal even when there is an uncorrelated portion around 1H of the composite video signal. It is to provide a circuit.

[発明の構成] (課題を解決するための手段) この輝度信号・色信号分離回路に係る第1の発明は、
複合映像信号を1H遅延させる第1の遅延手段と、前記複
合映像信号を色副搬送波周波数(3.58MHz)近傍を帯域
通過させる第1の帯域通過手段と、前記第1の遅延手段
の出力を3.58MHz近傍で帯域通過させる第2の帯域通過
手段と、この第2の帯域通過手段の出力を極性反転する
極性反転手段と、第2の帯域通過手段の出力を1H遅延さ
せる第2の遅延手段と、第1の帯域通過手段の出力と極
性反転手段の出力と第2の遅延信号の出力とを入力し、
中間レベルの信号を出力する第1の中間値検出手段と、
この第1の中間値検出手段の出力と極性反転手段の出力
と交流分を除去した信号を入力し、中間レベルの信号を
出力する第2の中間値検出手段と、この第2の中間値検
出手段の出力と第1の遅延手段の出力を加算する加算手
段とを具備し、第2の中間値検出手段より輝度信号成分
の混入しない色信号を得、加算手段より色信号成分の混
入しない輝度信号を得るものである。[Structure of the Invention] (Means for Solving the Problems) A first invention according to the luminance signal / chrominance signal separation circuit is as follows.
First delay means for delaying the composite video signal by 1H, first band-pass means for band-passing the composite video signal in the vicinity of the color subcarrier frequency (3.58 MHz), and 3.58 output from the first delay means. Second band-pass means for band-passing near MHz, polarity inversion means for inverting the polarity of the output of the second band-pass means, and second delay means for delaying the output of the second band-pass means by 1H. Receiving the output of the first band-pass means, the output of the polarity inversion means, and the output of the second delay signal,
First intermediate value detection means for outputting an intermediate level signal;
A second intermediate value detecting means for inputting an output of the first intermediate value detecting means, an output of the polarity inverting means and a signal from which an AC component is removed, and outputting an intermediate level signal; Means for adding the output of the means and the output of the first delay means, to obtain a color signal free of the luminance signal component from the second intermediate value detecting means, and to obtain the luminance free of the color signal component from the addition means. Get the signal.

また、第2の発明は、第1の発明における第1の中間
値検出手段に対して第2の帯域通過手段の出力を極性反
転手段を通さずに供給する構成にしたものである。According to a second aspect of the present invention, the output of the second band-pass means is supplied to the first intermediate value detecting means in the first aspect without passing through the polarity inverting means.

また、第3の発明は、第1の発明における第1の中間
値検出手段に対して供給する第2の遅延手段の出力と第
2の中間値検出手段に対して供給する交流分を除去した
信号とを入れ替えた構成としたものである。In the third invention, the output of the second delay means supplied to the first intermediate value detecting means and the AC component supplied to the second intermediate value detecting means in the first invention are removed. This is a configuration in which signals are replaced.

更に、第4の発明は、複合映像信号を1H遅延させる第
1の遅延手段と、この第1の遅延手段の出力をさらに1H
遅延させる第2の遅延手段と、前記複合映像信号を3.58
MHz近傍で帯域通過させる第1の帯域通過手段と、前記
第1の遅延手段の出力を3.58MHz近傍で帯域通過させる
第2の帯域通過手段と、前記第2の遅延手段の出力を3.
58MHz近傍で帯域通過させる第3の帯域通過手段と、第
2の帯域通過手段の出力を極性反転する極性反転手段
と、第1の帯域通過手段の出力と前記極性反転手段の出
力と交流分を除去した信号とを入力とし、中間レベルの
信号を出力する第1の中間値検出手段と、第3の帯域通
過手段の出力と前記極性反転手段の出力と交流分を除去
した信号とを入力とし、中間レベルの信号を出力する第
2の中間値検出手段と、第1,第2の中間値検出手段の各
出力と前記極性反転手段の出力とを入力とし、中間レベ
ルの信号を出力する第3の中間値検出手段と、この第3
の中間値検出手段の出力と前記第1の遅延手段の出力と
を加算する加算手段とを具備し、第3の中間値検出手段
より輝度信号成分の混入しない色信号を得、加算手段よ
り色信号成分の混入しない輝度信号を得るものである。Further, in the fourth invention, a first delay means for delaying the composite video signal by 1H, and an output of the first delay means for further 1H
Second delay means for delaying the composite video signal by 3.58
A first band-pass means for band-passing in the vicinity of MHz, a second band-pass means for band-passing the output of the first delay means in the vicinity of 3.58 MHz, and an output of the second delay means in 3.
A third band-pass means for band-passing near 58 MHz, a polarity inversion means for inverting the polarity of the output of the second band-pass means, and an AC component between the output of the first band-pass means and the output of the polarity inversion means. A first intermediate value detecting means for receiving the removed signal as an input and outputting a signal of an intermediate level, an output of the third band-passing means, an output of the polarity inverting means, and a signal from which an AC component has been removed is input. A second intermediate value detecting means for outputting a signal of an intermediate level, and outputs of the first and second intermediate value detecting means and an output of the polarity reversing means as inputs, and outputting a signal of an intermediate level. 3 intermediate value detecting means and the third intermediate value detecting means.
And an adding means for adding the output of the intermediate value detecting means and the output of the first delay means. A color signal free of a luminance signal component is obtained from the third intermediate value detecting means. This is to obtain a luminance signal in which no signal component is mixed.

(作用) 本発明においては、1H遅延回路、3.58MHz帯域通過フ
ィルタ、及び中間値検出回路等を用いて、輝度信号成分
の混入のない色信号を得、かつ垂直方向にもなまり等解
像度低下のない色信号を得ることができる。輝度信号に
ついても色信号成分の混入がなく、かつ垂直方向にもな
まり等の解像度低下のない信号を得ることができる。(Operation) In the present invention, a 1H delay circuit, a 3.58 MHz band-pass filter, an intermediate value detection circuit, and the like are used to obtain a color signal free from mixing of a luminance signal component and to reduce the resolution such as dullness in the vertical direction. No color signal can be obtained. Also for the luminance signal, it is possible to obtain a signal without mixing of the color signal components and without a decrease in resolution such as dullness in the vertical direction.

(実施例) 以下、図面に基づいて本発明の実施例について説明す
る。第1図は本発明に係る輝度信号・色信号分離回路の
構成を示すブロック図である。(Example) Hereinafter, an example of the present invention is described based on a drawing. FIG. 1 is a block diagram showing a configuration of a luminance signal / color signal separation circuit according to the present invention.

この図において、端子11は複合映像信号の入力端子で
ある。12及び13は1H遅延回路、14及び15は3.58MHz成分
を通過させる帯域通過フィルタ(BPF)である。また、
回路16及び21は中間値検出回路であり、本件出願人が特
許出願した特願昭60−216395号明細書に記載されている
ものと同様である。17は極性反転回路、18は加算回路で
ある。端子19は輝度信号出力端子、端子20は色信号出力
端子である。また、端子22には交流分(AC)を除去した
信号が加えられる。In this figure, a terminal 11 is an input terminal for a composite video signal. Reference numerals 12 and 13 denote 1H delay circuits, and reference numerals 14 and 15 denote bandpass filters (BPFs) that pass 3.58 MHz components. Also,
Circuits 16 and 21 are intermediate value detection circuits, and are the same as those described in Japanese Patent Application No. 60-216395 filed by the present applicant. 17 is a polarity inversion circuit, and 18 is an addition circuit. Terminal 19 is a luminance signal output terminal, and terminal 20 is a chrominance signal output terminal. Further, a signal from which an alternating current component (AC) has been removed is applied to the terminal 22.

上記中間値検出回路16は3つの最小値回路23,24,25と
1つの最大値回路26で構成されており、回路21について
も同様の回路構成である。最小値回路23,24,25は複数入
力の呈するレベルのうち最小レベルを選択的に出力する
ものであり、最大値回路26は複数入力の呈するレベルの
うち最大レベルを選択する回路である。そして、中間値
検出回路16は入力される(c),(d),(e)の信号
の呈するレベルのうち中間レベルを出力する回路であ
る。The intermediate value detection circuit 16 is composed of three minimum value circuits 23, 24, 25 and one maximum value circuit 26, and the circuit 21 has the same circuit configuration. The minimum value circuits 23, 24, and 25 selectively output the minimum level among the levels presented by a plurality of inputs, and the maximum value circuit 26 is a circuit that selects the maximum level from the levels presented by a plurality of inputs. The intermediate value detection circuit 16 is a circuit that outputs an intermediate level among the levels of the input signals (c), (d), and (e).

上記回路の動作を第2図を参照しながら説明する。第
2図中(a)〜(h)の波形は第1図中に示す各点
(a)〜(h)の波形に対応する。The operation of the above circuit will be described with reference to FIG. The waveforms (a) to (h) in FIG. 2 correspond to the waveforms at points (a) to (h) shown in FIG.

まず、入力端子11に第2図(a)に示すような複合映
像信号が入力されたとする。ここで、複合映像信号は1H
ごとにY信号とC信号の組として示し、簡単のため同期
信号は省略してある。この複合映像信号は、その映像信
号部分について図示のように1H区間の前後に相関のない
部分と相関のある部分とを有している。遅延回路12の出
力は1H遅延されて第2図(b)に示すような信号とな
る。(a)及び(b)の信号は帯域通過フィルタ14及び
15により帯域制限され極性反転回路17で反転されて
(c)及び(d)となる。また、フィルタ15の周力は遅
延回路13により1H遅延されて(e)となる。(c),
(d)及び(e)の信号を入力とした中間値検出回路16
の出力(f)は、中間値検出回路21により(d)及び端
子22のAC=0信号と比較され(g)となる。First, it is assumed that a composite video signal as shown in FIG. Here, the composite video signal is 1H
Each is shown as a set of a Y signal and a C signal, and a synchronization signal is omitted for simplicity. The composite video signal has an uncorrelated portion and a correlated portion before and after the 1H section as shown in the figure for the video signal portion. The output of the delay circuit 12 is delayed by 1H to become a signal as shown in FIG. The signals of (a) and (b) are
The band is limited by 15 and inverted by the polarity inverting circuit 17 to obtain (c) and (d). Further, the peripheral force of the filter 15 is delayed by 1H by the delay circuit 13 to become (e). (C),
An intermediate value detection circuit 16 having the signals (d) and (e) as inputs.
The output (f) is compared with (d) and the AC = 0 signal at the terminal 22 by the intermediate value detection circuit 21 to become (g).

(g)の波形は第2図からも判るように複合映像信号
から輝度成分が混入することなく分離されており、かつ
垂直方向の非相関部においてもなまり等の劣化のない色
信号となる。As can be seen from FIG. 2, the waveform (g) is separated from the composite video signal without mixing a luminance component, and becomes a color signal free from deterioration such as dullness even in a vertical non-correlation part.

(g)の信号はまた加算回路8により(b)の信号に
加算され輝度信号(h)が得られる。輝度信号もまた色
信号の混入がなく、かつ、垂直方向の非相関部において
もなまり等の劣化のない信号が得られる。The signal (g) is also added to the signal (b) by the addition circuit 8 to obtain a luminance signal (h). The luminance signal is also free of color signal mixing, and a signal free from deterioration such as dullness in a vertical non-correlation part is obtained.

第3図は第1図の中間値検出回路16及び21の他の実施
例であり、3つの最小値回路23〜25に代りに3つの最大
値回路27〜29を用い、最大値回路26に代えて最小値回路
30を用いた構成である。なお、第3図の回路を第1図の
回路16又は21の一方に用いても同様の効果がある。ま
た、中間値検出回路は3つの入力に対して対称であるか
ら、極性反転回路17がそれぞれの他の入力波形(c)ま
たは(e)を反転する様に構成されてもよい。FIG. 3 shows another embodiment of the intermediate value detection circuits 16 and 21 shown in FIG. 1. In FIG. Instead, the minimum value circuit
This is a configuration using 30. The same effect can be obtained by using the circuit in FIG. 3 for one of the circuits 16 and 21 in FIG. Further, since the intermediate value detection circuit is symmetrical with respect to three inputs, the polarity inversion circuit 17 may be configured to invert each of the other input waveforms (c) and (e).

さらに、極性反転回路17を同相回路とする(即ち、回
路17を無くす)ことにより、第1図の端子20には輝度信
号成分が得られることも推察できるので、本発明の他の
実施例として第4図の構成も可能である。Further, it can be inferred that a luminance signal component can be obtained at the terminal 20 in FIG. 1 by making the polarity inversion circuit 17 an in-phase circuit (that is, eliminating the circuit 17). The configuration of FIG. 4 is also possible.

第4図において、18A,18Bは新たに設けた加算回路で
あり、第5図は第4図における各部(a)〜(c),
(d)′,(d),(e),(f)′,(g)′,
(g)(h)の波形を示している。入力される複合映像
信号(a)及びこれを1H遅延した信号(b)は、帯域通
過フィルタ14及び15により帯域制限されて(c)及び
(d)′となる。信号(d)′は反転されて(d)とな
り、1H遅延されて(e)となる。(c),(d)′及び
(e)の信号を入力とした中間値検出回路16の出力
(f)は、中間値検出回路21により(d)′及び端子22
のAC=0の信号と比較され、(g)′となる。信号
(g)′は(d)と加算回路18Bで加算され、色信号
(g)となる。また、(b),(d),(g)′の信号
は加算回路18A及び18Bにて加算されて輝度信号(h)と
なる。色信号(g)、輝度信号(h)とも、それぞれに
輝度成分、色成分の混入がなく、垂直方向の非相関部に
おいてもなまり等の劣化のない信号が得られる。In FIG. 4, reference numerals 18A and 18B denote addition circuits newly provided, and FIG. 5 shows each part (a) to (c),
(D) ', (d), (e), (f)', (g) ',
(G) and (h) show the waveforms. The input composite video signal (a) and the signal (b) obtained by delaying the composite video signal by 1H are band-limited by the band-pass filters 14 and 15 to become (c) and (d) '. The signal (d) 'is inverted to become (d), and is delayed by 1H to become (e). The output (f) of the intermediate value detection circuit 16 to which the signals (c), (d) 'and (e) are input is output by the intermediate value detection circuit 21 to (d)' and the terminal 22.
(G) '. The signal (g) 'is added to the signal (d) by the adding circuit 18B to form a color signal (g). The signals (b), (d) and (g) 'are added by the adders 18A and 18B to become a luminance signal (h). Both the color signal (g) and the luminance signal (h) do not contain a luminance component and a color component, respectively, and a signal without deterioration such as dullness in a vertical non-correlation part can be obtained.

また、輝度信号、色信号の双方を本発明により得るこ
とに限らず、一方を従来の方法例えば従来のくし形フィ
ルタ回路により得てもよい。Further, both the luminance signal and the chrominance signal are not limited to be obtained by the present invention, and one of them may be obtained by a conventional method, for example, a conventional comb filter circuit.

さらに、第3図に示した中間値検出回路の入出力をVA
〜VDとし、VA〜VDをファジィ(Fuzzy)集合とすれば VD=(VA∨VB)∧(VC∨VA) ……(1) で表わされる。したがって、第1図の(c)〜(g)及
び端子22の信号をそれぞれVc〜Vg及びVQとすると Vg=(Vf∧Vd)∨(Vd∧VQ)∨(VQ∧Vf) ……(2) で表わされる。Vfは Vf=(Vc∧Vd)∨(Vd∧Ve)∨(Ve∧Vc) ……(3) であるから(2)及び(3)色より ここで、 Vf=(Vc∧Vd)∨(Vd∧VQ)∨(VQ∧Vc) ……(5) とすれば式(4)は Vg=(Vf∧Vd)∨(Vd∧Ve)∨(Ve∧Vf) ……(6) となる。つまり、式(5)及び(6)は式(2)及び
(3)のVeとVQを入れ替えたものと等価であることを示
している。したがって、第1図において(e)と端子22
の信号を入れ替えても同等の効果を有することになる。
これを第6図に本発明の他の実施例として示す。Further, the input and output of the intermediate value detection circuit shown in FIG. 3 V A
And ~V D, represented the V A ~V D fuzzy if (Fuzzy) set V D = (V A ∨V B ) ∧ (V C ∨V A) ...... (1). Therefore, when the first view (c) ~ (g) and a signal terminal 22 respectively and Vc~Vg and V Q Vg = (Vf∧Vd) ∨ (Vd∧V Q) ∨ (V Q ∧Vf) ... .. (2) Since Vf is Vf = (Vc∧Vd) ∨ (Vd∧Ve) ∨ (Ve∧Vc) (3), from the colors (2) and (3), Here, Vf = (Vc∧Vd) ∨ ( Vd∧ VQ) ∨ (V Q ∧Vc) ...... (5) Tosureba formula (4) is Vg = (Vf∧Vd) ∨ (Vd∧Ve ) ∨ (Ve∧Vf) (6) That is, equation (5) and (6) indicates that it is equivalent to that obtained by rearranging the Ve and V Q of the formula (2) and (3). Therefore, in FIG.
Even if the signals are replaced, the same effect is obtained.
This is shown in FIG. 6 as another embodiment of the present invention.

同様にして、第1図の(c)及び端子22を入れ替えた
場合も同等の効果をもっている。Similarly, the same effect is obtained when the terminal 22 is replaced with (c) in FIG.

これらの実施例に限らず式(2)及び(3)で表わさ
れたものと等価のものは全て同等の効果をもつことはい
うまでもない。It goes without saying that not only these embodiments but also those equivalent to the expressions (2) and (3) have the same effect.

第7図の本発明のさらに別の実施例を示すものであ
る。FIG. 7 shows still another embodiment of the present invention shown in FIG.

この図に示す実施例においては、複合映像信号の入力
端子11に1H遅延回路12,13を直列に接続してあり、回路1
2,13の入出力点にそれぞれ3.58MHzの帯域通過フィルタ1
4,15A,15Bを接続し、さらに3つの中間値検出回路16A,1
6B,21を用いた構成としてある。中間値検出回路16A,16B
に接続した端子22A,22BはAC=0とした信号の入力端子
である。In the embodiment shown in this figure, 1H delay circuits 12, 13 are connected in series to the input terminal 11 of the composite video signal, and the circuit 1
3.58MHz bandpass filter 1 at 2,13 input / output points
4,15A, 15B, and three intermediate value detection circuits 16A, 1
6B and 21 are used. Intermediate value detection circuits 16A, 16B
22A and 22B are input terminals for signals with AC = 0.

上記回路の動作を第8図を参照しながら説明する。 The operation of the above circuit will be described with reference to FIG.

第8図(a)は入力端子11に入力される複合映像信号
で、1H区間の前後に相関のない部分と相関のある部分と
を有している。第8図(a)の信号は、遅延回路12によ
り1H遅延され、第8図(b)に示す信号となり、遅延回
路13によりさらに1H遅延され、第8図(e)′に示す信
号となる。(a),(b),(e)′に示す信号は、帯
域通過フィルタ14及び15A及び15Bにより帯域制限され、
さらに帯域通過フィルタ15Aの出力信号は極性反転回路1
7により極性反転され、第8図(c),(d),(e)
に示す信号となる。端子22Aに加えられる信号はAC=0
であるから、第8図(c),(d)及びAC=0の信号を
入力とする中間値検出回路16Aの出力は第8図(f)′
となる。また端子22Bに加えられる信号もAC=0であ
り、第8図(d),(e)及びAC=0の信号を入力とす
る中間値検出回路16Bの出力は(f)″となる。さら
に、第8図(f)′,(f)″,(d)の信号は中間値
検出回路21に入力され、その出力は第8図(g)に示す
信号となる。(g)の波形は第8図からも判る様に複合
映像信号から輝度成分が混入することなく分離されてお
り、かつ垂直方向の非相関部においてもなまり等の劣化
のない色信号となる。(g)の信号は端子20より色信号
として出力される。(g)の信号は加算回路18により
(b)の信号に加算され輝度信号(h)が得られる。輝
度信号も、色信号の混入がなく、かつ垂直方向の非相関
部においてもなまり等の劣化のない信号が得られる。FIG. 8 (a) shows a composite video signal input to the input terminal 11, which has an uncorrelated portion and a correlated portion before and after the 1H section. The signal in FIG. 8A is delayed by 1H by the delay circuit 12 to become the signal shown in FIG. 8B, and further delayed by 1H by the delay circuit 13 to become the signal shown in FIG. 8E '. . The signals shown in (a), (b) and (e) 'are band-limited by band-pass filters 14 and 15A and 15B,
Further, the output signal of the bandpass filter 15A is applied to the polarity inversion circuit 1
7 (c), (d), (e)
The signal shown in FIG. The signal applied to terminal 22A is AC = 0
Therefore, the output of the intermediate value detection circuit 16A which receives the signals of FIGS. 8 (c) and 8 (d) and the signal of AC = 0 is shown in FIG. 8 (f) '.
Becomes The signal applied to the terminal 22B is also AC = 0, and the output of the intermediate value detection circuit 16B which receives the signals of FIGS. 8 (d) and 8 (e) and the signal AC = 0 is (f) ″. 8 (f) ', (f) "and (d) are input to the intermediate value detection circuit 21, and the output is the signal shown in FIG. 8 (g). As can be seen from FIG. 8, the waveform (g) is separated from the composite video signal without mixing luminance components, and becomes a color signal free from deterioration such as dullness even in a vertical non-correlation part. The signal (g) is output from the terminal 20 as a color signal. The signal (g) is added to the signal (b) by the adding circuit 18 to obtain a luminance signal (h). As for the luminance signal, it is possible to obtain a signal without mixing of the color signal and without deterioration such as dullness even in a non-correlation part in the vertical direction.

[発明の効果] 以上述べたように本発明によれば、1Hの前後で信号に
相関があるなしに依らず効果的に輝度信号と色信号を分
離することが可能となり、輝度信号及び色信号の互いの
残留成分による妨害がなく、かつ輝度及び色信号の垂直
方向の解像度低下を伴うことがないので再現画像の画質
を向上させることができる。[Effects of the Invention] As described above, according to the present invention, it is possible to effectively separate a luminance signal and a chrominance signal regardless of whether or not there is a correlation between signals before and after 1H. Of the luminance components and the vertical resolution of the luminance signal and the chrominance signal are not reduced, so that the quality of the reproduced image can be improved.

【図面の簡単な説明】[Brief description of the drawings]

第1図は本発明の一実施例の輝度信号・色信号分離回路
を示すブロック図、第2図は第1図の動作説明図、第3
図は第1図の中間値検出回路の他の実施例を示すブロッ
ク図、第4図は本発明の他の実施例を示すブロック図、
第5図は第4図の動作説明図、第6図は本発明の他の実
施例を示すブロック図、第7図は本発明の他の実施例を
示すブロック図、第8図は第7図の動作説明図、第9図
はNTSC方式の複合映像信号の周波数分布を説明する説明
図、第10図は従来の輝度信号・色信号分離回路の一例を
示すブロック図、第11図は第10図の動作説明図、第12図
は入力される信号の1H前後に相関がない場合における第
10図の動作説明図である。 11……複合映像信号入力端子、 12,13……1H遅延回路、 14,15,15A,15B……帯域通過フィルタ、 16,16A,16B,21……中間値検出回路、 17……極性反転回路、 18,18A,18B……加算回路、 19……輝度信号出力端子、 20……色信号出力端子。FIG. 1 is a block diagram showing a luminance signal / chrominance signal separation circuit according to one embodiment of the present invention, FIG. 2 is an operation explanatory diagram of FIG. 1, and FIG.
FIG. 4 is a block diagram showing another embodiment of the intermediate value detection circuit of FIG. 1, FIG. 4 is a block diagram showing another embodiment of the present invention,
FIG. 5 is an operation explanatory view of FIG. 4, FIG. 6 is a block diagram showing another embodiment of the present invention, FIG. 7 is a block diagram showing another embodiment of the present invention, and FIG. FIG. 9 is an explanatory diagram for explaining the frequency distribution of a composite video signal of the NTSC system, FIG. 10 is a block diagram showing an example of a conventional luminance / chrominance signal separation circuit, and FIG. FIG. 10 is an operation explanatory diagram of FIG. 10, and FIG. 12 is a diagram of FIG.
FIG. 11 is an operation explanatory diagram of FIG. 10; 11 Composite video signal input terminal 12,13 1H delay circuit 14,15,15A, 15B Bandpass filter 16,16A, 16B, 21 Intermediate value detection circuit 17 Polarity inversion Circuit, 18, 18A, 18B: Addition circuit, 19: Luminance signal output terminal, 20: Color signal output terminal.

Claims (4)

(57)【特許請求の範囲】(57) [Claims] 【請求項1】入力される複合映像信号を1水平期間遅延
し第1の遅延信号を得る第1の遅延手段と、 前記複合映像信号を入力とし色副搬送波周波数近傍を通
過させる第1の帯域通過手段と、 前記第1の遅延信号を入力とし色副搬送波周波数近傍を
通過させる第2の帯域通過手段と、 この第2の帯域通過手段の出力を極性反転する極性反転
手段と、 前記第2の帯域通過手段の出力を1水平期間遅延し第2
の遅延信号を得る第2の遅延手段と、 前記第1の帯域通過手段の出力と前記極性反転手段の出
力と前記第2の遅延信号とを入力としこれら信号の中間
レベルを検出する第1の中間値検出手段と、 この第1の中間値検出手段の出力と前記極性反転手段の
出力と交流分を除去した信号とを入力としこれら信号の
中間レベルを検出することにより、輝度信号成分の混入
していない色信号を得る第2の中間値検出手段と、 この第2の中間値検出手段の出力と前記第1の遅延信号
とを加算し、色信号成分の混入していない輝度信号を得
る加算手段と、 を具備したことを特徴とする輝度信号・色信号分離回
路。A first delay means for delaying an input composite video signal by one horizontal period to obtain a first delay signal; a first band receiving the composite video signal as input and passing near a color subcarrier frequency Passing means; second band-pass means for receiving the first delay signal as input and passing near the color subcarrier frequency; polarity inverting means for inverting the polarity of the output of the second band-pass means; Delays the output of the band-pass means for one horizontal period.
A second delay means for obtaining a delayed signal of the first type; a first delay means for receiving an output of the first band-pass means, an output of the polarity inverting means, and the second delayed signal, and detecting an intermediate level of these signals; Intermediate value detection means, and the output of the first intermediate value detection means, the output of the polarity inversion means, and the signal from which the AC component has been removed are input, and the intermediate level of these signals is detected to mix the luminance signal component. A second intermediate value detecting means for obtaining a color signal which has not been processed, and an output of the second intermediate value detecting means and the first delay signal are added to obtain a luminance signal in which a color signal component is not mixed. A luminance signal / chrominance signal separation circuit, comprising: an addition unit. 【請求項2】入力される複合映像信号を1水平期間遅延
し第1の遅延信号を得る第1の遅延手段と、 前記複合映像信号を入力とし色副搬送波周波数近傍を通
過させる第1の帯域通過手段と、 前記第1の遅延信号を入力とし色副搬送波周波数近傍を
通過させる第2の帯域通過手段と、 この第2の帯域通過手段の出力を極性反転する極性反転
手段と、 前記第2の帯域通過手段の出力を1水平期間遅延し第2
の遅延信号を得る第2の遅延手段と、 前記第1の帯域通過手段の出力と前記第2の帯域通過手
段の出力と前記第2の遅延信号とを入力としこれら信号
の中間レベルを検出する第1の中間値検出手段と、 この第1の中間値検出手段の出力と前記第2の帯域通過
手段の出力と交流分を除去した信号とを入力としこれら
信号の中間レベルを検出する第2の中間値検出手段と、 この第2の中間値検出手段の出力と前記極性反転手段の
出力とを加算し、輝度信号成分の混入していない色信号
を得る第1の加算手段と、 前記第1の遅延信号と前記極性反転手段の出力と前記第
2の中間値検出手段の出力とを加算し、色信号成分の混
入していない輝度信号を得る第2の加算手段と、 を具備したことを特徴とする輝度信号・色信号分離回
路。2. A first delay means for delaying an input composite video signal by one horizontal period to obtain a first delay signal, and a first band receiving said composite video signal as input and passing near a color subcarrier frequency. Passing means; second band-pass means for receiving the first delay signal as input and passing near the color subcarrier frequency; polarity inverting means for inverting the polarity of the output of the second band-pass means; Delays the output of the band-pass means for one horizontal period.
A second delay means for obtaining a delayed signal of the following, an input of the output of the first band-pass means, an output of the second band-pass means and the second delayed signal, and detection of an intermediate level of these signals A first intermediate value detecting means, a second intermediate value detecting means for receiving an output of the first intermediate value detecting means, an output of the second band-pass means and a signal from which an AC component has been removed, and detecting an intermediate level of these signals. Intermediate value detection means, and first addition means for adding an output of the second intermediate value detection means and an output of the polarity inversion means to obtain a color signal free of a luminance signal component; A second adding means for adding the delay signal of No. 1, the output of the polarity inverting means and the output of the second intermediate value detecting means to obtain a luminance signal in which no color signal component is mixed. A luminance / chrominance signal separation circuit. 【請求項3】入力される複合映像信号を1水平期間遅延
し第1の遅延信号を得る第1の遅延手段と、 前記複合映像信号を入力とし色副搬送波周波数近傍を通
過させる第1の帯域通過手段と、 前記第1の遅延信号を入力とし色副搬送波周波数近傍を
通過させる第2の帯域通過手段と、 この第2の帯域通過手段の出力を極性反転する極性反転
手段と、 前記第2の帯域通過手段の出力を1水平期間遅延し第2
の遅延信号を得る第2の遅延手段と、 前記第1の帯域通過手段の出力と前記極性反転手段の出
力と交流分を除去した信号とを入力としこれら信号の中
間レベルを検出する第1の中間値検出手段と、 この第1の中間値検出手段の出力と前記極性反転手段の
出力と前記第2の遅延信号とを入力としこれら信号の中
間レベルを検出することにより、輝度信号成分の混入し
ていない色信号を得る第2の中間値検出手段と、 この第2の中間値検出手段の出力と前記第1の遅延信号
とを加算し、色信号成分の混入していない輝度信号を得
る加算手段と、 を具備したことを特徴とする輝度信号・色信号分離回
路。3. A first delay means for delaying an input composite video signal by one horizontal period to obtain a first delay signal, and a first band which receives the composite video signal as input and passes near a color subcarrier frequency. Passing means; second band-pass means for receiving the first delay signal as input and passing near the color subcarrier frequency; polarity inverting means for inverting the polarity of the output of the second band-pass means; Delays the output of the band-pass means for one horizontal period.
A second delay means for obtaining a delay signal of the following, and an input of an output of the first band-pass means, an output of the polarity inversion means and a signal from which an AC component has been removed, and detecting an intermediate level of these signals. Intermediate value detecting means, and the output of the first intermediate value detecting means, the output of the polarity inverting means, and the second delay signal are input, and the intermediate level of these signals is detected to mix the luminance signal component. A second intermediate value detecting means for obtaining a color signal which has not been processed, and an output of the second intermediate value detecting means and the first delay signal are added to obtain a luminance signal in which a color signal component is not mixed. A luminance signal / chrominance signal separation circuit, comprising: an addition unit. 【請求項4】入力される複合映像信号を1水平期間遅延
し第1の遅延信号を得る第1の遅延手段と、 前記第1の遅延信号をさらに1水平期間遅延し第2の遅
延信号を得る第2の遅延手段と、 前記複合映像信号を入力とし色副搬送波周波数近傍を通
過させる第1の帯域通過手段と、 前記第1の遅延信号を入力とし色副搬送波周波数近傍を
通過させる第2の帯域通過手段と、 前記第2の遅延信号を入力とし色副搬送波周波数近傍を
通過させる第3の帯域通過手段と、 前記第2の帯域通過手段の出力を極性反転する極性反転
手段と、 前記第1の帯域通過手段の出力と前記極性反転手段の出
力と交流分を除去した信号とを入力としこれら信号の中
間レベルを検出する第1の中間値検出手段と、 前記第3の帯域通過手段の出力と前記極性反転手段の出
力と交流分を除去した信号とを入力としこれら信号の中
間レベルを検出する第2の中間値検出手段と、 前記第1の中間値検出手段の出力と前記第2の中間値検
出手段の出力と前記極性反転手段の出力とを入力としこ
れら信号の中間レベルを検出することにより、輝度信号
成分の混入していない色信号を得る第3の中間値検出手
段と、 この第3の中間値検出手段の出力と前記第1の遅延信号
とを加算し、色信号成分の混入していない輝度信号を得
る加算手段と、 を具備したことを特徴とする輝度信号・色信号分離回
路。4. A first delay means for delaying an input composite video signal by one horizontal period to obtain a first delay signal; and further delaying the first delay signal by one horizontal period to produce a second delay signal. A second delay means for obtaining, a first band-pass means for receiving the composite video signal as input and passing near a color subcarrier frequency, and a second band-pass means for receiving the first delayed signal as input and passing near the color subcarrier frequency A third band-pass unit that receives the second delay signal as input and passes near the color subcarrier frequency, a polarity inversion unit that reverses the polarity of the output of the second band-pass unit, A first intermediate value detection unit that receives an output of the first band-pass unit, an output of the polarity inversion unit, and a signal from which an AC component is removed, and detects an intermediate level of these signals; and the third band-pass unit Output and the polarity inversion means Second intermediate value detection means for receiving an output and a signal from which an AC component has been removed as input, and detecting an intermediate level of these signals; an output of the first intermediate value detection means and an output of the second intermediate value detection means A third intermediate value detecting means for obtaining a color signal in which a luminance signal component is not mixed by detecting an intermediate level of these signals by inputting the third intermediate value and the output of the polarity inverting means; A luminance signal / color signal separation circuit, comprising: an addition unit for adding an output of the unit and the first delay signal to obtain a luminance signal in which a color signal component is not mixed.
JP15446488A 1988-06-21 1988-06-21 Luminance signal / color signal separation circuit Expired - Lifetime JP2635693B2 (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
JP15446488A JP2635693B2 (en) 1988-06-21 1988-06-21 Luminance signal / color signal separation circuit

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP15446488A JP2635693B2 (en) 1988-06-21 1988-06-21 Luminance signal / color signal separation circuit

Publications (2)

Publication Number Publication Date
JPH01319387A JPH01319387A (en) 1989-12-25
JP2635693B2 true JP2635693B2 (en) 1997-07-30

Family

ID=15584816

Family Applications (1)

Application Number Title Priority Date Filing Date
JP15446488A Expired - Lifetime JP2635693B2 (en) 1988-06-21 1988-06-21 Luminance signal / color signal separation circuit

Country Status (1)

Country Link
JP (1) JP2635693B2 (en)

Also Published As

Publication number Publication date
JPH01319387A (en) 1989-12-25

Similar Documents

Publication Publication Date Title
JPS6123492A (en) Y/c separating device
US4920408A (en) Circuit for separating composite color television signal into luminance signal and chrominance signal
JP2692897B2 (en) Luminance signal / color signal separation circuit
JP2635693B2 (en) Luminance signal / color signal separation circuit
JPH0366287A (en) Signal separator
JP2698637B2 (en) Luminance signal / chrominance signal separation circuit
JPH02108390A (en) Luminance signal and chrominance signal separating circuit for pal color television signal
JPS595794A (en) Dot disturbance removing device
JP2782814B2 (en) Video signal correlation circuit and Y / C separation device
JPS63187894A (en) Color signal processing circuit
JPH053573A (en) Luminance signal/chrominance signal separator circuit
JPH06292230A (en) Luminance signal separator circuit
JPH0371786A (en) Luminance signal chrominance signal separator circuit
JP2557511B2 (en) Motion detection circuit for television display screen
JP2649254B2 (en) FM transmission receiver for color television signal
JPH0391398A (en) Secam color signal processing circuit
JPH08242464A (en) Color television receiver
JPS63149980A (en) Y/c separation circuit
JPH04351090A (en) Y/c separation device
JPH053571A (en) Luminance signal/chrominance signal separator circuit
JPH05219521A (en) Device for separating luminance signal from chrominance signal
JPH06292227A (en) Luminance signal/chrominance signal separator
JPH0622332A (en) Luminance signal/chrominance signal separator circuit, television receiver or video signal recording and reproducing device
JPH01213092A (en) Chrominance signal removing circuit
JPH04105494A (en) Luminance signal/chrominance signal separator