JP3719314B2 - Television signal processing apparatus and method, and recording medium - Google Patents

Description

【００７２】
つまり、行列Ｘの１つの行は、所定の入力データの組（正規方程式）を表し、その行数は学習期間に記憶したサンプルの数を示している。例えば、行列Ｘの第１行の行列要素ｘ11,ｘ12,ｘ13,ｘ14、およびｘ15は、それぞれ、画素ａ乃至ｅのデータ（画素データ）を表しており、この組で１つの入力データを表している。行列Ｙの１つの行の値は、教師信号の値を表し、その行数は学習期間に記憶したサンプルの数を示している。式（１）と式（２）の場合、所定のクラスに分類されたｎ個（ただし、ｎ＞＞５）の入力データの組がサンプルとして、学習期間に記憶されたことを示している。
【００７３】
そして、式（３）で表される行列Ｗの行列要素（係数）を、方程式Ｙ=ＸＷの誤差が小さくなるように、最小自乗法を用いて決定する。
【００７４】
【数２】

【００７５】
ここで、行列Ｗの行列要素の求め方についての簡単な説明を行う。いま、式（４）で表されるエラー行列Ｅを考える。
【００７６】
【数３】

【００７７】
すると、残差方程式ＸＷ=Ｙ+Ｅにおいて、各行列要素Wi(i=1,2,3,4,5)の最確値は、最小自乗法により、式（５）を最小にする行列要素Wi(i=1,2,3,4,5)として求めることができる。
【００７８】
【数４】

【００７９】
従って、停留原理により、式（６）、すなわち、式（７）が成立する行列要素Wj(j=1,2,3,4,5)を求めることで、最確値を与える行列Ｗ（係数）を生成することができる。
【００８０】
【数５】

【００８１】
ここで、残差方程式ＸＷ=Ｙ+Ｅの両辺を、行列要素wj(j=1,2,3,4,5)で偏微分することにより、式（８−１）乃至式（８−５）が得られる。
【００８２】
【数６】

【００８３】
従って、式（７）は、式（８−１）乃至式（８−５）を用いて、式（９−１）乃至式（９−５）のように表すことができる。
【００８４】
【数７】

【００８５】
式（９−１）乃至式（９−５）と、残差方程式ＸＷ=Ｙ+Ｅを用いて、式（１０−１）乃至式（１０−５）で示す正規方程式が得られる。
【００８６】
【数８】

【００８７】
式（１０−１）乃至式（１０−５）は、5個の未知数(w1,w2,w3,w4,w5)を含む5本の方程式であるため、これらの方程式を、例えば、掃き出し法を用いて行列Ｗの行列要素を求めることができる。このようにして求められた、各クラス毎の係数は、係数ＲＯＭ８７（係数ＲＯＭ４６）に記憶される。
【００８８】
以上のようにして、図６のステップＳ５で生成（分類）されたクラスに対応する係数のセットが、ステップＳ６で、係数ＲＯＭ４６から線形１次結合積和演算回路４８に供給されると、後続のステップＳ７で、ＦＩＦＯ回路４２より映像信号がブロック化回路４７に供給される。そして、ブロック化回路４７の各遅延素子６１−１乃至６１−ｎで各タップに対応するブロック画素信号が生成された後、複数の画素から構成されるブロック画素信号は、線形１次結合積和演算回路４８に供給される。線形１次結合積和演算回路４８の乗算回路７１−１乃至７１−ｎは、係数ＲＯＭ４６より読み出された各タップに対応する係数を用いて、ブロック化回路４７より供給されたブロック画素信号各々に対し、対応する係数を乗じて、加算回路７２に出力する。加算回路７２は、これらの信号を加え合わせた後、リミッタ７３に供給する。
【００８９】
例えば、図９に示すラインの場合、注目画素ｃの信号値を求めるとき、ブロック化回路４７より供給された画素ａ乃至ｅに対応するブロック画素信号に対し、係数ＲＯＭ４６から読みだした画素ａ乃至ｅに対応する係数を乗じて、それらを加えた信号をリミッタ７３に出力する。具体的には、例えば、画素ａ乃至ｅに対応する係数が、それぞれ、0,0,1,0,0であり、その画素値がＡ，Ｂ，Ｃ，Ｄ，Ｅである場合、注目画素ｃの信号値は、0*Ａ+0*Ｂ+1*Ｃ+0*Ｄ+0*Ｅ=Ｃとなり、この信号がリミッタ７３に供給される。また、例えば、画素ａ乃至ｅに対応する係数が、それぞれ、0,1,0,0,0である場合、注目画素ｃの信号値は、0*Ａ+1*Ｂ+0*Ｃ+0*Ｄ+0*Ｅ=Ｂとなる。このように、係数ＲＯＭ４６に記憶された係数により、映像信号の所定の走査線の画素を所定の時間だけ、進ませたり、遅延させたりすることができる。
【００９０】
そして、加算回路７２で１つの信号にまとめられた映像信号は、リミッタ７３で、その信号レベルの範囲が制限された後、図示しないＤ／Ａ変換回路によりアナログ映像信号に変換され、そのアナログ映像信号が映像処理回路３４に出力される。このようにして、ジッタを補正した映像信号が生成される。
【００９１】
後続のステップＳ８で、時間軸補正回路３２より出力された映像信号は、映像処理回路３４で、復調、増幅などの所定の処理が施された後、ＣＲＴ３６に出力される。また、チューナ３１から音声処理回路３３に入力された音声信号は、音声処理回路３３で復調、増幅などの所定の処理が施された後、スピーカ３５に出力される。
【００９２】
図１０は、時間軸補正回路３２を用いて、図１３に示した搬送色信号と同一の搬送色信号を補正した信号を示している。図１０において、所定のフィールドの第１９８ラインに対応する搬送色信号は実線で、第２００ラインに対応する搬送色信号は点線で、第２０２ラインに対応する搬送色信号は一点鎖線で、それぞれ、示してある。
【００９３】
また、図１０に示した第１９８ラインの搬送色信号と第２０２ラインの搬送色信号の相関値、第１９８ラインの搬送色信号と第２００ラインの搬送色信号の相関値、および第２００ラインの搬送色信号と第２０２ラインの搬送色信号の相関値を求めると、それぞれ、0.968523,-0.968028,または-0.972247となった。これらの値は、図１３における値と比較し、その絶対値の値が大きくなっている。従って、時間軸補正回路３２より出力される搬送色信号は、ジッタが軽減された良質の画質を実現する信号となる。
【００９４】
図１１は、時間軸補正回路３２の他の実施の形態の構成を示すブロック図である。図１１の時間軸補正回路３２において、図２の場合と対応する部分には、同一の符号を付してあり、その説明は適宜省略する。
【００９５】
図１１に示す時間軸補正回路３２においては、スイッチ９２が端子９２ｂ側に接続されているとき、線形１次結合積和演算回路４８の出力（デジタル映像信号）を、移動平均補正回路８１に供給する。移動平均補正回路８１は、移動平均補正回路４１の処理動作と同様の処理動作により、輝度成分を取り除き、スイッチ９２の端子９２ｂを介してＦＩＦＯ回路４３に供給するようになされている。すなわち、スイッチ９２は、最初のラインの処理のときのみ、端子９２ａ側に接続されており、２番目以降のラインの処理のときは、端子９２ｂ側に接続されるようになされている。従って、２番目以降のラインの相関値を求める処理においては、既に、ジッタ補正の処理が行われた、その直前のラインの搬送色信号がＦＩＦＯ回路４３で１ライン分遅延され、この搬送色信号（ジッタ補正後の映像信号）との比較により、相関値が求められる。なお、図１１の時間軸補正回路３２の他の処理動作は、図２の時間軸補正回路３２の処理動作と、同様の処理であるため、その説明は省略する。
【００９６】
図１２は、時間軸補正回路３２のさらに他の実施の形態の構成を示すブロック図である。図１２において、図１１の場合と対応する部分には、同一の符号を付してあり、その説明は適宜省略する。
【００９７】
図１２の時間軸補正回路３２においては、図１１の時間軸補正回路３２の移動平均補正回路４１，８１と、相関値演算回路４４に代えて、Ｙ／Ｃ分離回路１０１，１０２と、動き検出回路１０３が設けられている。その他の構成は、図１１における場合と同様である。
【００９８】
所定のラインと、それに隣接するラインにおいては、ジッタが少なければ相関が高いので、両者の間における動きは小さいことになる。従って、ジッタが多ければ、相関が少なくなり、動きが大きくなる。そこで、動きから２つのラインの相関（ジッタ）を判定することができる。図１２の例はこの原理に基づいている。
【００９９】
そこで、図１２の例においては、Ｙ／Ｃ分離回路１０１またはＹ／Ｃ分離回路１０２で輝度信号（Ｙ信号）が分離され、この輝度信号が動き検出回路１０３とスイッチ９２を介してＦＩＦＯ回路４３に供給される（但し、Ｙ／Ｃ分離回路１０１からＦＩＦＯ回路４３に供給される輝度信号は、最初のラインのみで、２番目以降のラインの相関値を求める処理においては、既に、ジッタ補正の処理が行われた、Ｙ／Ｃ分離回路１０２からの輝度信号となる）。
【０１００】
そして、動き検出回路１０３は、Ｙ／Ｃ分離回路１０１より入力される輝度信号と、ＦＩＦＯ回路４３より入力される１ライン前の輝度信号の動きを検出する。この動きは、ジッタが多ければ大きくなり、少なければ小さくなるので、係数ＲＯＭ４６からこの動き（相関）に対応する係数を出力することで、上述した場合と同様の動作を実現することができる。なお、この場合の係数ＲＯＭ４６に記憶されているクラス毎の係数のセットを学習処理によって求める際に決定されるクラスは、Ｙ／Ｃ分離回路及び動き検出回路を用いて求められることは言うまでもない。
【０１０１】
このようにして、従来の図１４に示す構造のＴＢＣ１を用いずに、ＴＶ信号に含まれているジッタを軽減させることができる。
【０１０２】
また、図２に示す時間軸補正回路３２は、図１４に示すような書き込みクロック発生回路（ＰＬＬ）１３を用いずに構成することができる。
【０１０３】
なお、上記実施の形態においては、係数ＲＯＭ４６に記憶する係数は、最小自乗法を用いて求めるようにしたが、他の方法を用いて求めた係数を記憶させるようにしてもよい。また、本発明は、ＴＶ受像機の他、ＶＣＲやその他の電子機器などにも応用することができる。
【０１０４】
また、上述したように、本発明の実施の形態において、所定の注目画素に対して、クラスコードを決定しているが、本発明はこれに限らず、所定のブロック毎に、クラスコードを決定するようにしてもよい。
【０１０５】
さらに、本発明の実施の形態は、ブロック図を用いてハードウェアをして実現しているが、本発明はこれに限らず、ＣＰＵやメモリなどを用いてソフトウェアで実現することも可能である。
【０１０６】
なお、上記したような処理を行うプログラムをユーザに伝送する伝送媒体としては、磁気ディスク、CD-ROM、固体メモリなどの記録媒体の他、ネットワーク、衛星などの通信媒体を利用することができる。
【０１０７】
なお、本発明の主旨を逸脱しない範囲において、さまざまな変形や応用例が考えうる。従って、本発明の要旨は、実施の形態に限定されるものではない。
【０１０８】
【発明の効果】
以上のように、請求項１に記載のテレビジョン信号処理装置、請求項１０に記載のテレビジョン信号処理方法、および請求項１１に記載の記録媒体によれば、第１の走査線と、第１の走査線に隣接する第２の走査線の相関を表す相関値を演算し、その相関値を量子化することにより得られたクラスコードに基づいて読み出された係数を入力映像信号との線形１次演算に適用して、所定の遅延時間に対応する前記テレビジョン信号を生成するようにし、また、クラスコードの生成においては、第１の走査線の第１の搬送色信号と、第１の走査線に隣接する第２の走査線の第２の搬送色信号との相関値を演算し、その演算を、第２の走査線の第２の搬送色信号の代りに、ジッタ補正された映像信号の第１の走査線の第１の搬送色信号を用いて行うようにしたので、テレビジョン信号に含まれている時間軸変動を確実に補正することができる。
【０１０９】
また、請求項１２に記載のテレビジョン信号処理装置、請求項２１に記載のテレビジョン信号処理方法、および請求項２２に記載の記録媒体によれば、第１の走査線と、第１の走査線に隣接する第２の走査線の動き量を検出することにより得られたクラスコードに基づいて読み出された係数を入力映像信号との線形１次演算に適用して、所定の遅延時間に対応する前記テレビジョン信号を生成するようにし、また、クラスコードの生成においては、第２の走査線の第２の輝度信号の代りに、ジッタ補正された映像信号の第１の走査線の第１の輝度信号を用いた動き量の演算を行うようにしたので、テレビジョン信号に含まれている時間軸変動を確実に補正することができる。
【図面の簡単な説明】
【図１】本発明におけるテレビジョン信号処理装置を応用したＴＶ受像機２１の一実施の形態の構成を示すブロック図である。
【図２】図１の時間軸補正回路３２の一実施の形態の構成を示すブロック図である。
【図３】図２の移動平均補正回路４１の一実施の形態の構成を示すブロック図である。
【図４】図２のブロック化回路４７の一実施の形態の構成を示すブロック図である。
【図５】図２の線形１次結合積和演算回路４８の一実施の形態の構成を示すブロック図である。
【図６】図１のＴＶ受像機２１の処理動作を説明するフローチャートである。
【図７】係数ＲＯＭ４６に記憶されているクラス毎の係数のセットを生成する演算装置８１の一実施の形態の構成を示すブロック図である。
【図８】係数ＲＯＭ４６に記憶されているクラス毎の係数のセットを生成するための処理動作を示すフローチャートである。
【図９】所定のラインの注目画素に対応する信号値の算出方法を説明する図である。
【図１０】図２の時間軸補正回路３２によりジッタが補正された、所定の走査線に対応するＴＶ信号を示すグラフである。
【図１１】図１の時間軸補正回路３２の他の実施の形態の構成を示すブロック図である。
【図１２】図１の時間軸補正回路３２のさらに他の実施の形態の構成を示すブロック図である。
【図１３】ジッタが含まれている所定の走査線に対応するＴＶ信号を示すグラフである。
【図１４】従来のＴＢＣの一例の構成を示すブロック図である。
【符号の説明】
１ ＴＢＣ， １１ Ｈ/Ｖ同期分離回路， １２ Ａ/Ｄ変換回路， １３ 書き込みクロック発生回路， １４ メモリ， １５ 書き込みアドレスカウンタ， １６ Ｄ/Ａ変換回路， １７ 読み出しアドレスカウンタ， １８ ジャンプ検出回路， １９ 読み出しクロック発生回路， ２１ ＴＶ受像機， ２２ アンテナ， ３１ チューナ， ３２ 時間軸補正回路， ３３ 音声処理回路， ３４ 映像処理回路， ３５ スピーカ， ３６ ＣＲＴ， ４１ 移動平均補正回路， ４２，４３ ＦＩＦＯ回路， ４４ 相関値演算回路， ４５ 量子化回路， ４６ 係数ＲＯＭ， ４７ ブロック化回路， ４８ 線形１次積和演算回路， ５１ 移動平均算出回路， ５２ ディレイ回路， ５３ 減算回路， ５４ 加算回路， ６１−１乃至６１−ｎ 遅延素子， ７１−１乃至７１−ｎ 乗算回路， ７２ 加算回路， ７３ リミッタ， ８１ 演算装置， ８２ デジタルＶＣＲ， ８３ Ｄ/Ａコンバータ， ８４ ＶＣＲ， ８５ Ａ/Ｄ変換回路， ８６ 係数決定回路， ９１ 移動平均補正回路， ９２ スイッチ[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to a television signal processing apparatus and method, andrecoding mediaIn particular, a television signal that maximizes the correlation defined by the carrier color signal corresponding to a predetermined scanning line constituting a predetermined field and the carrier color signal corresponding to the adjacent scanning line is generated. TV signal processing apparatus and method for performing time axis correction (jitter removal), andrecoding mediaAbout.
[0002]
[Prior art]
A television (TV) signal broadcast from a television (TV) broadcasting station or a TV signal reproduced by an analog VCR (Video Cassette Recorder) includes time axis fluctuation (jitter), and jitter. If the TV signal including is displayed on the monitor as it is, the line slightly moves to the left and right, and high quality image quality cannot be obtained.
[0003]
FIG. 13 shows three lines of carrier color signals in a predetermined field in a TV signal including jitter. In FIG. 13, the carrier color signal of the 198th line in a predetermined (even) field is indicated by a solid line, the carrier color signal of the 200th line is indicated by a dotted line, and the carrier color signal of the 202nd line is indicated by an alternate long and short dash line. .
[0004]
Since the phase of the carrier color signal of each line is modulated corresponding to the color signal of each line, the phase of the carrier color signal of different lines basically does not match. However, since there is a correlation between adjacent lines, the correlation value is a relatively large value. However, if there is jitter, this correlation value becomes small.
[0005]
The correlation value between the 198th line carrying color signal and the 202nd line carrying color signal, the 198th line carrying color signal and the 200th line carrying color signal, and the 200th line carrying color shown in FIG. When the correlation value between the signal and the carrier color signal of the 202nd line was obtained, it was 0.913390, -0.103358, or -0.104299, respectively.
[0006]
The correlation value between the carrier color signal of the 198th line and the carrier color signal of the 202nd line is a positive value, whereas the correlation value between the carrier color signal of the 198th line and the carrier color signal of the 200th line, or the 200th line. The correlation value between the carrier color signal of the line and the carrier color signal of the 202nd line is a negative value. This is because the reference phase of the carrier color signal is the same in the former, and the latter two are the opposite phases of the reference phase of the carrier color signal.
[0007]
The larger the absolute value of the correlation value, the less the influence of jitter and the more the phases are aligned. In this example, the absolute value of the correlation value between the 198th line and the 200th line and the correlation value between the 200th line and the 202nd line are both as small as 0.103358 or 0.104299. The absolute value of the correlation value between the 198th line and the 202nd line is relatively large at 0.913390, but it is not sufficient.
[0008]
Therefore, jitters are removed by using TBC (Time Base Corrector) in commercial equipment and consumer high-end equipment.
[0009]
FIG. 14 is a block diagram showing a configuration of an example of a conventional TBC.
[0010]
A TV signal broadcast and received from a TV broadcasting station, or a TV signal obtained by reproducing a predetermined VCR, for example, a consumer VCR, is input to the H / V sync separation circuit 11 and the A / D conversion circuit 12 of the TBC 1. The The H / V synchronization separation circuit 11 separates the horizontal synchronization (H) signal and the vertical synchronization (V) signal from the TV signal and outputs them to the write clock generation circuit 13.
[0011]
A write clock generation circuit (PLL) 13 generates a write clock synchronized with the vertical synchronization signal and the horizontal synchronization signal, and supplies it to the A / D conversion circuit 12 and the write address counter 15. The A / D conversion circuit 12 converts an analog TV signal into a digital signal in synchronization with the write clock supplied from the write clock generation circuit 13 and supplies the digital signal to the memory 14.
[0012]
The write address counter 15 increases a predetermined counter value in synchronization with the write clock supplied from the write clock generation circuit 13 and supplies the counter value to the memory 14. The memory 14 stores the digital signal supplied from the A / D conversion circuit 12 at an address corresponding to the counter value supplied from the write address counter 15.
[0013]
The read clock generation circuit 19 includes a fixed crystal oscillation circuit and the like, generates a read clock having a constant frequency, and supplies the read clock to the D / A conversion circuit 16 and the read address counter 17.
[0014]
The jump detection circuit 18 detects a difference between a write address and a read address (a counter value of the write address counter 15 and a counter value of the read address counter 17), and the difference is within a predetermined value (ideally a constant value). The read address counter 17 is controlled so that the difference becomes a predetermined value when it greatly changes.
[0015]
The read address counter 17 increases a predetermined counter value in synchronization with the clock supplied from the read clock generation circuit 19 and outputs it to the memory 14. The memory 14 reads a digital signal stored at an address corresponding to the counter value supplied from the read address counter 17 and supplies the digital signal to the D / A conversion circuit 16. The digital signal output from the memory 14 is converted into an analog signal by the D / A conversion circuit 16 and then supplied to a predetermined signal processing circuit (not shown).
[0016]
In this way, a write clock that is locked to the phase of the carrier color signal is generated using the synchronization signal included in the TV signal, writing is performed using this write clock, and reading is performed using a read clock having a constant phase. By doing so, the jitter is removed.
[0017]
[Problems to be solved by the invention]
However, conventionally, there is only a method of using the TBC having the above-described structure as a method for reducing jitter included in a TV signal, and there is a problem that selection options are narrow.
[0018]
Conventionally, when the TBC used for business equipment is used for consumer equipment, a special circuit (chroma conversion circuit or the like) is required, and there is a problem that the circuit configuration increases.
[0019]
The present invention has been made in view of such a situation, and is intended to reduce jitter contained in a TV signal without using a conventional TBC having the above-described structure.
[0020]
[Means for Solving the Problems]
  The television signal processing apparatus according to claim 1, an extraction unit that extracts a carrier color signal of a predetermined scanning line of a predetermined field of a video signal, a first carrier color signal of a first scanning line, Class code generation means for generating a class code based on the correlation with the second transport color signal of the second scan line adjacent to one scan line, and a coefficient corresponding to the class based on the class code Coefficient generating means for generating a set of video signals, and video signal generating means for generating a video signal subjected to jitter correction from the generated coefficient set and the video signal.The class code generating means is a computing means for computing a correlation value between the first carrier color signal of the first scanning line and the second carrier color signal of the second scanning line adjacent to the first scanning line. And the calculating means includes the first carrier color signal of the first scanning line of the jitter-corrected video signal generated by the video signal generating means instead of the second carrier color signal of the second scanning line. Calculate the correlation value usingIt is characterized by that.
[0021]
  Claim 10The television signal processing method described in 1) includes an extraction step of extracting a carrier color signal of a predetermined scanning line of a predetermined field of a video signal, a first carrier color signal of a first scanning line, and a first scanning. A class code generating step for generating a class code based on the correlation with the second carrier color signal of the second scanning line adjacent to the line, and a set of coefficients corresponding to the class based on the class code. A coefficient generation step, and a video signal generation step for generating a jitter-corrected video signal from the generated coefficient set and the video signal.In the class code generation step, the correlation value between the first carrier color signal of the first scanning line and the second carrier color signal of the second scanning line adjacent to the first scanning line is calculated. A first carrier color signal of the first scanning line of the jitter-corrected video signal generated by the processing of the video signal generation step, instead of the second carrier color signal of the second scanning line. The correlation value is calculated usingIt is characterized by that.
[0022]
  Claim 11Described inrecoding mediaIs a step of extracting a carrier color signal of a predetermined scanning line in a predetermined field of the video signal, a first carrier color signal of the first scanning line, and a second scanning adjacent to the first scanning line. A class code generating step for generating a class code based on the correlation of the line with the second carrier color signal, a coefficient generating step for generating a set of coefficients corresponding to the class based on the class code, and generation A video signal generation step for generating a jitter-corrected video signal from the set of coefficients and the video signal.In the class code generation step, the correlation value between the first carrier color signal of the first scanning line and the second carrier color signal of the second scanning line adjacent to the first scanning line is calculated. A first carrier color signal of the first scanning line of the jitter-corrected video signal generated by the processing of the video signal generation step, instead of the second carrier color signal of the second scanning line. The correlation value is calculated usingIt is characterized by that.
[0023]
  Claim 12The television signal processing apparatus described in 1) includes an extraction unit that extracts a luminance signal of a predetermined scanning line of a predetermined field of a video signal, a first luminance signal of the first scanning line, and a first scanning line. Class code generating means for generating a class code based on the amount of motion between the second luminance signals of adjacent second scanning lines, and generating a set of coefficients corresponding to the class based on the class code Coefficient generating means for generating, and video signal generating means for generating a jitter-corrected video signal from the generated coefficient set and the video signal.The class code generating means uses the first luminance signal of the first scanning line of the jitter-corrected video signal generated by the video signal generating means, instead of the second luminance signal of the second scanning line. To calculate the amount of movementIt is characterized by that.
[0024]
  Claim 21The television signal processing method described in 1) includes an extraction step of extracting a luminance signal of a predetermined scanning line of a predetermined field of a video signal, a first luminance signal of the first scanning line, and a first scanning line. A class code generation step for generating a class code based on the amount of motion between the second luminance signals of adjacent second scanning lines, and a set of coefficients corresponding to the class are generated based on the class code. A coefficient generation step, and a video signal generation step for generating a jitter-corrected video signal from the generated coefficient set and the video signal;In the processing of the class code generation step, instead of the second luminance signal of the second scanning line, the jitter of the first scanning line of the video signal generated by the processing of the video signal generation step The amount of motion is calculated using the first luminance signal.It is characterized by that.
[0025]
  Claim 22Described inrecoding mediaIs a step of extracting a luminance signal of a predetermined scanning line of a predetermined field of the video signal, a first luminance signal of the first scanning line, and a second scanning line adjacent to the first scanning line. A class code generating step for generating a class code based on the amount of motion between the second luminance signal and a coefficient generating step for generating a set of coefficients corresponding to the class based on the class code; A video signal generating step for generating a jitter-corrected video signal from the set of coefficients and the video signal;In the processing of the class code generation step, instead of the second luminance signal of the second scanning line, the jitter of the first scanning line of the video signal generated by the processing of the video signal generation step The amount of motion is calculated using the first luminance signal.It is characterized by that.
[0026]
  The television signal processing device according to claim 1,Claim 10A television signal processing method according to claim 1, andClaim 11Described inrecoding media, A class code is generated based on the correlation between the first carrier color signal of the first scan line and the second carrier color signal of the second scan line adjacent to the first scan line. The Based on the generated class code, a set of coefficients corresponding to the class is generated, and a video signal subjected to jitter correction is generated from the generated set of coefficients and the video signal.In generating the class code, a correlation value between the first carrier color signal of the first scanning line and the second carrier color signal of the second scanning line adjacent to the first scanning line is calculated. The The calculation is performed using the first carrier color signal of the first scanning line of the video signal whose jitter has been corrected, instead of the second carrier color signal of the second scanning line.
[0027]
  Claim 12A television signal processing device according to claim 1,Claim 21A television signal processing method according to claim 1, andClaim 22Described inrecoding media, A class code is generated based on the amount of motion between the first luminance signal of the first scanning line and the second luminance signal of the second scanning line adjacent to the first scanning line. The Then, a coefficient set corresponding to the generated class is generated, and a video signal subjected to jitter correction is generated from the coefficient set and the video signal.In the generation of the class code, the motion amount is calculated using the first luminance signal of the first scanning line of the video signal subjected to jitter correction instead of the second luminance signal of the second scanning line. Done.
[0028]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below, but in order to clarify the correspondence between each means of the invention described in the claims and the following embodiments, in parentheses after each means, The features of the present invention will be described with the corresponding embodiment (however, an example) added. However, of course, this description does not mean that each means is limited to the description.
[0029]
  The television signal processing apparatus according to claim 1 includes extraction means (for example, a moving average correction circuit 41 in FIG. 2) for extracting a carrier color signal of a predetermined scanning line in a predetermined field of a video signal, and first scanning. Class code generating means for generating a class code based on the correlation between the first carrier color signal of the line and the second carrier color signal of the second scanning line adjacent to the first scanning line (for example, FIG. 2 quantization circuit 45), coefficient generation means (for example, coefficient ROM 46 in FIG. 2) for generating a set of coefficients corresponding to the class based on the class code, and the generated coefficient set and video signal. Video signal generating means (for example, linear linear combination product-sum operation circuit 48 in FIG. 2) for generating a video signal subjected to jitter correction.The class code generating means calculates a correlation value between the first carrier color signal of the first scanning line and the second carrier color signal of the second scanning line adjacent to the first scanning line. Means (for example, the correlation value calculation circuit 44 in FIG. 2), and the calculation means replaces the jitter-corrected video signal generated by the video signal generation means instead of the second carrier color signal of the second scanning line. A correlation value is calculated using the first carrier color signal of the first scanning line.It is characterized by that.
[0030]
The television signal processing apparatus according to claim 2, wherein the coefficient generation means stores storage means (storage unit) for storing a set of coefficients for each class, and sets of coefficients corresponding to the class code based on the class code. It has a reading means (reading part) which reads.
[0031]
  A television signal processing apparatus according to claim 6 is provided.,Quantization means for quantizing the calculated correlation value and generating the quantization code as a class code (for example, the quantization circuit 45 in FIG. 2)Further haveIt is characterized by that.
[0032]
  Claim 12The television signal processing apparatus described in 1) extracts extraction means (for example, Y / C separation circuit 101 in FIG. 12) for extracting a luminance signal of a predetermined scanning line in a predetermined field of the video signal, and the first scanning line. Class code generating means for generating a class code based on the amount of movement between the luminance signal of 1 and the second luminance signal of the second scanning line adjacent to the first scanning line (for example, the movement of FIG. 12). Detection circuit 103 and quantization circuit 45), coefficient generation means (for example, coefficient ROM 46 in FIG. 12) for generating a set of coefficients corresponding to the class based on the class code, generated coefficient set and video signal And a video signal generating means (for example, linear linear combination product-sum operation circuit 48 in FIG. 12) for generating a video signal subjected to jitter correction.The class code generating means uses the first luminance signal of the first scanning line of the jitter-corrected video signal generated by the video signal generating means, instead of the second luminance signal of the second scanning line. To calculate the amount of movementIt is characterized by that.
[0033]
  Claim 13In the television signal processing apparatus described in the above, the coefficient generation unit reads out the coefficient set corresponding to the class code based on the storage unit (storage unit) that stores the coefficient set for each class and the class code. Means (reading unit).
[0034]
  Claim 18The television signal processing apparatus described in (1) is characterized in that the extraction means includes Y / C separation means (for example, the Y / C separation circuit 101 in FIG. 12) for extracting a luminance signal.
[0035]
Embodiments of the present invention will be described below, but the “circuit” used in the drawings should be interpreted in a broad sense and is not limited to the present embodiments. In other words, this includes a hardware circuit, processing by a computer loaded with software, a microprocessor and a microcomputer, and combinations thereof.
[0036]
FIG. 1 is a block diagram showing a configuration of an embodiment of a television (TV) receiver 21 to which the television signal processing apparatus of the present invention is applied. In the following description, a case where an NTSC television (TV) signal is received from a television broadcasting station will be described. The same can be applied.
[0037]
An NTSC system TV signal from a television broadcasting station is received by an antenna 22, and a predetermined television (TV) broadcasting channel is selected by a tuner 31 of a TV receiver 21. The video signal output from the tuner 31 is supplied to the time axis correction circuit 32. The audio signal output from the tuner 31 is supplied to the audio processing circuit 33. The audio processing circuit 33 performs processing such as demodulation and amplification on the input audio signal and outputs the processed signal to the speaker 35.
[0038]
The time axis correction circuit 32 extracts the carrier color signal multiplexed in the video signal and delays the carrier color signal corresponding to a predetermined line (scanning line) and the line (scanning line) adjacent thereto. The correlation (correlation value) of the carrier color signals is calculated. The time axis correction circuit 32 obtains a delay time that maximizes the absolute value of the correlation value (reduces jitter), and a video signal delayed by a time corresponding to the delay time (jitter is corrected (reduced)). Video signal) is calculated using a predetermined arithmetic expression described later, thereby generating a video signal with corrected jitter. The video signal whose jitter has been corrected is output to the video processing circuit 34. The video processing circuit 34 performs processing such as demodulation and amplification on the video signal with corrected jitter supplied from the time axis correction circuit 32 and supplies it to a CRT (cathode ray tube) 36.
[0039]
The details of the time axis correction circuit 32 in the present invention will be described below with reference to the drawings.
[0040]
FIG. 2 is a block diagram showing a configuration of an embodiment of the time axis correction circuit 32. As shown in FIG. The video signal of the TV signal supplied from the tuner 31 is supplied to a moving average correction circuit 41 and a FIFO (First in First Out) circuit 42 of the time axis correction circuit 32. The supplied video signal is supplied to the moving average correction circuit 41 and the FIFO circuit 42 as a digital video signal digitized by an A / D (Analog-Digital) conversion circuit (not shown). The moving average correction circuit 41 extracts, for example, a carrier color signal multiplexed on the video signal based on a digital video signal corresponding to four consecutive pixels, and adds 128 to the signal level, thereby adding 0 to 0. After being converted into a carrier color signal having a signal level of 255, this signal is supplied to a first in first out (FIFO) circuit 43 and a correlation value calculation circuit 44.
[0041]
The FIFO circuit 43 delays the carrier color signal of a predetermined line constituting the predetermined field supplied from the moving average correction circuit 41 by a predetermined time, and then outputs the delayed signal to the correlation value calculation circuit 44. . That is, the FIFO circuit 43 delays the carrier color signal of a predetermined line supplied from the moving average correction circuit 41 by, for example, a time corresponding to one line, and then outputs it to the correlation value calculation circuit 44. ing.
[0042]
The correlation value calculation circuit 44 calculates the correlation between the carrier color signal supplied from the moving average correction circuit 41 and the carrier color signal delayed by the FIFO circuit 43, and supplies the correlation value to the quantization circuit 45. Has been made.
[0043]
The quantization circuit 45 shifts the correlation value supplied from the correlation value calculation circuit 44 to an appropriate level, performs rounding processing, converts it into an integer quantization code (class code), and outputs it to the coefficient ROM 46. It is made like that. The coefficient ROM 46 includes a storage unit that stores the coefficient and a reading unit that reads the coefficient stored in the storage unit, and has an address corresponding to the quantization code (class code) supplied from the quantization circuit 45. A set of coefficients corresponding to each stored tap is read out and supplied to the linear linear combination product-sum operation circuit 48.
[0044]
The FIFO circuit 42 delays the digital video signal and outputs it to the blocking circuit 47 for a period until the coefficient set corresponding to each tap is supplied to the linear primary combined product-sum operation circuit 48. Has been made.
[0045]
The blocking circuit 47 converts the digital video signal supplied from the FIFO circuit 42 into a block pixel signal, that is, a pixel signal of a block unit including a pixel of interest and a plurality of pixels located in the vicinity of the pixel of interest on the same line. The data is converted and output to the linear primary combined product-sum operation circuit 48. At this time, the number of pixels included in the block pixel signal is equal to the number of coefficients in the coefficient set read from the coefficient ROM 46.
[0046]
As described above, the linear primary combined product-sum operation circuit 48 converts the coefficient set corresponding to each tap read from the coefficient ROM 46 and the block pixel signal corresponding to each tap supplied from the blocking circuit 47. On the other hand, linear linear combination processing is performed. That is, after the coefficient corresponding to the pixel value of each pixel of the block pixel signal is multiplied, a process of adding all these values is performed. The digital video signal generated in this way is converted to an analog video signal by a D / A (Digital to Analog) conversion circuit (not shown) and then output to the video processing circuit 34 as an output video signal. Yes. This output video signal becomes a video signal whose jitter has been corrected (reduced).
[0047]
FIG. 3 is a block diagram showing a configuration of an embodiment of the moving average correction circuit 41. The input digital video signal is supplied to the moving average calculation circuit 51 and the delay circuit 52 of the moving average correction circuit 41. The moving average calculation circuit 51 calculates an average value of video signals corresponding to a predetermined number of continuous pixels, for example, four pixels, and outputs the average value to the subtraction circuit 53.
[0048]
The subtraction circuit 53 extracts the carrier color signal by subtracting the video signal corresponding to the predetermined pixel supplied from the delay circuit 52 that delays by a plurality of pixels from the average value supplied from the moving average calculation circuit 51. , And is supplied to the adder circuit 54. The adder circuit 54 adds a 128-level signal to the input carrier color signal to convert it into a carrier color signal having any level of 0 to 255, and the FIFO circuit 43 and the correlation value calculation circuit 44. To be output.
[0049]
FIG. 4 is a block diagram showing a configuration of an embodiment of the blocking circuit 47. The clock CK is supplied to the clock input terminals of the delay elements 61-1 to 61-n. The video signal supplied from the FIFO circuit 42 is input to the signal input terminal of the delay element 61-1. Further, the outputs of the delay elements 61-1 to 61- (n-1) in the previous stage are supplied to the signal input terminals of the delay elements 61-2 to 61-n, respectively. . Then, a total of n outputs (outputs corresponding to the number of taps) of the delay elements 61-1 to 61-n are output to the linear primary combination product-sum operation circuit 48 as block pixel signals of one block. It is made like that. Therefore, in synchronization with the clock CK, the signals sequentially delayed by one pixel from the delay elements 61-1 to 61-n are simultaneously supplied to the linear primary combination arithmetic circuit 48 for a plurality (n) pixels. It is made to be supplied.
[0050]
FIG. 5 is a block diagram showing a configuration of an embodiment of the linear primary combined product-sum operation circuit 48. A set of n coefficients read from the coefficient ROM 46 is supplied to the multiplication circuits 71-1 to 71-n corresponding to each tap. Further, the block pixel signals for n pixels supplied from the blocking circuit 47 are supplied to the corresponding multiplication circuits 71-1 to 71-n.
[0051]
The multiplication circuits 71-1 to 71-n are configured to multiply each pixel value of the supplied block pixel signal by a corresponding coefficient from a given set of coefficients, and then output the result to the addition circuit 72. . The adder circuit 72 adds all the pixel signals multiplied by a predetermined coefficient for each block, generates a video signal with corrected (reduced) jitter, and supplies it to the limiter 73. This video signal is converted into an analog video signal after the signal level is limited to a predetermined range by a limiter 73 and supplied to the video processing circuit 34 as an output video signal.
[0052]
Next, the processing operation of the TV receiver 21 will be described with reference to the flowchart of FIG.
[0053]
In step S 1 of FIG. 6, a TV signal broadcast from a predetermined TV broadcast station is received by the antenna 22. A tuner 31 selects a predetermined TV broadcast channel.
[0054]
In subsequent step S <b> 2, the tuner 31 supplies the demodulated audio signal to the audio processing circuit 33 and supplies the demodulated video signal to the time axis correction circuit 32. This video signal is A / D converted by an A / D conversion circuit (not shown) of the time axis correction circuit 32 and then supplied to the moving average correction circuit 41 and the FIFO circuit 42 as a digital video signal. The FIFO circuit 42 delays the digital video signal until a coefficient set corresponding to each tap is read from the coefficient ROM 46.
[0055]
In the subsequent step 3, the moving average calculation circuit 51 of the moving average correction circuit 41 calculates the average value of the video signals corresponding to the continuous 4m pixels (where m is 1, 2,... Shows the number of When the average value of the continuous 4m pixels is input to the subtraction circuit 53, the delay circuit 52 outputs the data of the center pixel (target pixel) among the continuous 4m pixels. The subtraction circuit 53 calculates the difference between the two, thereby extracting the carrier color signal and outputting it to the addition circuit 54.
[0056]
That is, continuous pixel data constituting the same line of a predetermined field is represented by YI, YQ, where luminance data is Y, I signal data is I, and Q signal data is Q. , Y + I, Y + Q. Therefore, for example, if the data of four consecutive pixels is Y-I, Y-Q, Y + I, Y + Q, the average value is Y. Q is obtained by subtracting the average value Y from YQ (or Y + Q) which is data of an intermediate pixel among the four pixels. Therefore, Q signal data can be obtained based on the obtained value. Further, the I signal data can be obtained by performing the same calculation on the Y + I (or Y-I) pixel. Thus, the carrier color signal Q or I can be extracted by calculating the moving average to obtain luminance data and subtracting the data of a predetermined pixel.
[0057]
The adder circuit 54 adds the signal level of 128 to the extracted carrier color signal, and then outputs it to the FIFO circuit 43 and the correlation value calculation circuit 44.
[0058]
Next, in step S4, the FIFO circuit 43 delays the carrier color signal supplied from the moving average correction circuit 41 by the time of one line, and then outputs it to the correlation value calculation circuit 44. The correlation value calculation circuit 44 calculates the correlation between the carrier color signal of the target line supplied from the moving average correction circuit 41 and the carrier color signal delayed by the delay time of one line supplied from the FIFO circuit 43. The value is supplied to the quantization circuit 45.
[0059]
In the subsequent step S5, the correlation value supplied from the correlation value calculation circuit 44 is shifted to an appropriate level by the quantization circuit 45, rounded, and converted into an integer quantization code. . That is, the quantization code is obtained as a class (class code) corresponding to the correlation value, and this class code is supplied to the coefficient ROM 46.
[0060]
Subsequently, in step S <b> 6, the coefficient ROM 46 supplies a set of coefficients corresponding to each tap stored in the address corresponding to the quantization code (class code) to the linear primary combined product-sum operation circuit 48.
[0061]
Here, a method for generating a set of coefficients for each class stored in the coefficient ROM 46 (learning method) will be described with reference to FIG. 7, FIG. 8, and FIG.
[0062]
FIG. 7 is a block diagram showing a configuration of an embodiment of a computing device (learning device) 81 that generates a set of coefficients for each class stored in the coefficient ROM 46.
[0063]
A reference learning video signal for generating a coefficient set for each class is recorded in a digital VCR 82 in which jitter does not occur (jitter is sufficiently small) during reproduction. The digital video signal reproduced by the digital VCR 82 is converted into an analog video signal by the D / A conversion circuit 83 and then recorded on the consumer VCR 84.
[0064]
Next, the analog video signal of a predetermined sequence including jitter reproduced from the VCR 84 is converted into a digital video signal by the A / D conversion circuit 85 and supplied to the coefficient determination circuit 86. At this time, a digital video signal of the same sequence as the sequence reproduced by the VCR 84 is supplied from the digital VCR 82 to the coefficient determination circuit 86. The coefficient determination circuit 86 obtains a class (class code) from a video signal (digital video signal) including jitter supplied from the VCR 84, and a video signal (digital video signal) including jitter supplied from the VCR 84 for each class. And a digital video signal not including jitter supplied from the digital VCR 82, a normal equation (linear linear combination equation) is established. A set of prediction coefficients for each class can be obtained by applying the method of least squares to the normal equation established for each class and solving the normal equation for each class using a matrix solving method. This set of coefficients for each class is stored in the coefficient ROM 87 and from there to the coefficient ROM 46.
[0065]
That is, the coefficient determination circuit 86 is a predetermined two lines (scanning lines) of all video signals (digital video signals) supplied from the VCR 84 supplied during the learning period for obtaining a set of coefficients for each class. The correlation value between the carrier color signals corresponding to is obtained, and the correlation value is quantized to be converted into a quantization code (class code), whereby the video signal (for example, the target pixel) supplied from the VCR 84 is converted. Determine the corresponding class. Then, for each determined class, a predetermined normal equation (linear linear combination formula) for obtaining each target pixel of the teacher video signal (digital video signal supplied from the digital VCR 82) is supplied from the VCR 84. It is generated using the signal and the video signal supplied from the digital VCR 82. Then, the least square method is applied to the normal equation generated for each class, and a plurality of normal equations prepared for each class are solved by using a matrix solution method, whereby a set of coefficients for each class can be obtained.
[0066]
Specifically, the operation of generating a coefficient set for each class will be described in detail with reference to the flowchart of FIG. First, in step S11, a coefficient set generation process (learning process) for each class is started, and the process proceeds to a “data end” determination process in step S12. All video signals for the coefficient generation process (learning process) are processed. If it is determined whether or not all of the video signals have been processed, the process proceeds to class determination processing in step S13. In step S13, in order to determine the class corresponding to the video signal (target pixel) supplied from the VCR 84, processing similar to the processing operation for determining the quantization code (class code) shown in FIG. Execute. That is, the correlation between the carrier color signal corresponding to a predetermined line in a predetermined field of the video signal (digital video signal) supplied from the VCR 84 and the carrier color signal corresponding to a line delayed by one line is calculated, and the correlation is calculated. A quantization code (class code) is determined by quantizing the value. The details are the same as the processing operation for determining the quantization code (class code) shown in FIG.
[0067]
The class code (quantization code) is determined by the processing described above, and the process proceeds to the normal equation generation processing in step S14. In step S14, corresponding to the determined class code, the digital video signal (teacher video signal) supplied from the digital VCR 82 and the video signal (digital video signal) supplied from the VCR 84 are used as described later. A normal equation is generated, and the process returns to step S12. Such processing is executed for all the video signals, and after the processing of all the video signals is completed, the process proceeds to the coefficient determination processing in step S15.
[0068]
Next, in step S15, as will be described later, a set of coefficients for each class is determined by solving a normal equation for each class using a matrix solving method. Then, the process proceeds to a coefficient store process in step S16. In step S16, the determined coefficient set for each class is stored in the coefficient ROM 87, and then the process proceeds to step S17 to generate a coefficient set for each class (learning). Process) ends.
[0069]
The process of step S14 (normal equation generation process) and step S15 (coefficient determination process) in the flowchart of FIG. 8 will be described in more detail.
[0070]
As shown in FIG. 9, for example, assuming that pixels constituting a predetermined line are pixels a to e, for each class (class code) classified by the correlation value calculated by the above method in a predetermined learning period. , The video signal (digital video signal) supplied from the VCR 84 and the digital video signal (teacher video signal) representing the signal value of the target pixel supplied from the digital VCR 82 are stored as a matrix X or a matrix Y shown below, respectively. .
[0071]
[Expression 1]

[0072]
That is, one row of the matrix X represents a predetermined set of input data (normal equation), and the number of rows indicates the number of samples stored in the learning period. For example, the matrix elements x11, x12, x13, x14, and x15 in the first row of the matrix X represent data (pixel data) of the pixels a to e, respectively, and represent one input data in this set. Yes. The value of one row of the matrix Y represents the value of the teacher signal, and the number of rows indicates the number of samples stored during the learning period. In the case of Expression (1) and Expression (2), it is indicated that a set of n (n >> 5) input data classified into a predetermined class is stored as a sample during the learning period.
[0073]
Then, the matrix elements (coefficients) of the matrix W represented by Expression (3) are determined using the method of least squares so that the error of the equation Y = XW becomes small.
[0074]
[Expression 2]

[0075]
Here, a simple description of how to obtain the matrix elements of the matrix W will be given. Now, consider an error matrix E expressed by Equation (4).
[0076]
[Equation 3]

[0077]
Then, in the residual equation XW = Y + E, the most probable value of each matrix element Wi (i = 1, 2, 3, 4, 5) is the matrix element Wi that minimizes the expression (5) by the method of least squares. (i = 1, 2, 3, 4, 5).
[0078]
[Expression 4]

[0079]
Therefore, by obtaining the matrix element Wj (j = 1, 2, 3, 4, 5) in which the formula (6), that is, the formula (7) is established according to the stationary principle, the matrix W (coefficient) that gives the most probable value. Can be generated.
[0080]
[Equation 5]

[0081]
Here, both sides of the residual equation XW = Y + E are partially differentiated by the matrix element wj (j = 1, 2, 3, 4, 5), thereby obtaining the equations (8-1) to (8-5). ) Is obtained.
[0082]
[Formula 6]

[0083]
Therefore, Expression (7) can be expressed as Expression (9-1) to Expression (9-5) using Expression (8-1) to Expression (8-5).
[0084]
[Expression 7]

[0085]
Using equations (9-1) to (9-5) and the residual equation XW = Y + E, normal equations represented by equations (10-1) to (10-5) are obtained.
[0086]
[Equation 8]

[0087]
Since the equations (10-1) to (10-5) are five equations including five unknowns (w1, w2, w3, w4, w5), these equations are expressed by, for example, a sweeping method. By using this, the matrix element of the matrix W can be obtained. The coefficient for each class determined in this way is stored in the coefficient ROM 87 (coefficient ROM 46).
[0088]
As described above, when a set of coefficients corresponding to the class generated (classified) in step S5 in FIG. 6 is supplied from the coefficient ROM 46 to the linear linear combination product-sum operation circuit 48 in step S6, In step S 7, the video signal is supplied from the FIFO circuit 42 to the blocking circuit 47. Then, after the block pixel signal corresponding to each tap is generated by each of the delay elements 61-1 to 61-n of the blocking circuit 47, the block pixel signal composed of a plurality of pixels is converted into a linear linear combination product sum. This is supplied to the arithmetic circuit 48. Each of the multiplication circuits 71-1 to 71-n of the linear primary combined product-sum operation circuit 48 uses each of the block pixel signals supplied from the blocking circuit 47 using the coefficients corresponding to the respective taps read from the coefficient ROM 46. Is multiplied by the corresponding coefficient and output to the adder circuit 72. The adder circuit 72 adds these signals and supplies them to the limiter 73.
[0089]
For example, in the case of the line shown in FIG. 9, when the signal value of the target pixel c is obtained, the pixel a to pixel B read from the coefficient ROM 46 with respect to the block pixel signal corresponding to the pixel a to e supplied from the blocking circuit 47. The coefficient corresponding to e is multiplied and a signal obtained by adding them is output to the limiter 73. Specifically, for example, when the coefficients corresponding to the pixels a to e are 0, 0, 1,0, 0 and the pixel values are A, B, C, D, E, respectively, the target pixel The signal value of c is 0 * A + 0 * B + 1 * C + 0 * D + 0 * E = C, and this signal is supplied to the limiter 73. Further, for example, when the coefficients corresponding to the pixels a to e are 0,1,0,0,0, respectively, the signal value of the target pixel c is 0 * A + 1 * B + 0 * C + 0. * D + 0 * E = B. As described above, the pixels stored in the coefficient ROM 46 can advance or delay the pixels of a predetermined scanning line of the video signal by a predetermined time.
[0090]
The video signal combined into one signal by the adder circuit 72 is converted to an analog video signal by a D / A conversion circuit (not shown) after the signal level range is limited by a limiter 73. The signal is output to the video processing circuit 34. In this way, a video signal with corrected jitter is generated.
[0091]
In the subsequent step S8, the video signal output from the time axis correction circuit 32 is subjected to predetermined processing such as demodulation and amplification in the video processing circuit 34, and then output to the CRT 36. The audio signal input from the tuner 31 to the audio processing circuit 33 is subjected to predetermined processing such as demodulation and amplification by the audio processing circuit 33 and then output to the speaker 35.
[0092]
FIG. 10 shows a signal obtained by correcting the same carrier color signal as the carrier color signal shown in FIG. 13 by using the time axis correction circuit 32. In FIG. 10, the carrier color signal corresponding to the 198th line of the predetermined field is a solid line, the carrier color signal corresponding to the 200th line is a dotted line, and the carrier color signal corresponding to the 202nd line is a one-dot chain line. It is shown.
[0093]
Further, the correlation value between the carrier color signal of the 198th line and the carrier color signal of the 202th line, the correlation value of the carrier color signal of the 198th line and the carrier color signal of the 200th line, and the The correlation values of the carrier color signal and the carrier color signal of the 202nd line were 0.968523, -0.968028, or -0.972247, respectively. These values are larger in absolute value than the values in FIG. Therefore, the carrier color signal output from the time axis correction circuit 32 is a signal that realizes high quality image quality with reduced jitter.
[0094]
FIG. 11 is a block diagram showing a configuration of another embodiment of the time axis correction circuit 32. In the time axis correction circuit 32 of FIG. 11, the same reference numerals are given to the portions corresponding to those in FIG. 2, and the description thereof will be omitted as appropriate.
[0095]
In the time axis correction circuit 32 shown in FIG. 11, when the switch 92 is connected to the terminal 92 b side, the output (digital video signal) of the linear primary combined product-sum operation circuit 48 is supplied to the moving average correction circuit 81. To do. The moving average correction circuit 81 removes the luminance component and supplies the same to the FIFO circuit 43 via the terminal 92b of the switch 92 by a processing operation similar to the processing operation of the moving average correction circuit 41. That is, the switch 92 is connected to the terminal 92a only during the first line processing, and is connected to the terminal 92b side during the second and subsequent line processing. Therefore, in the processing for obtaining the correlation value of the second and subsequent lines, the carrier color signal of the immediately preceding line, for which the jitter correction processing has already been performed, is delayed by one line in the FIFO circuit 43, and this carrier color signal. A correlation value is obtained by comparison with (video signal after jitter correction). The other processing operations of the time axis correction circuit 32 in FIG. 11 are the same as the processing operations of the time axis correction circuit 32 in FIG.
[0096]
FIG. 12 is a block diagram showing a configuration of still another embodiment of the time axis correction circuit 32. 12, portions corresponding to those in FIG. 11 are denoted by the same reference numerals, and description thereof is omitted as appropriate.
[0097]
In the time axis correction circuit 32 of FIG. 12, instead of the moving average correction circuits 41 and 81 and the correlation value calculation circuit 44 of the time axis correction circuit 32 of FIG. A circuit 103 is provided. Other configurations are the same as those in FIG.
[0098]
  For a given line and adjacent lines, jitterButIf it is less, the correlation is high, so the movement between the two is small. Therefore, the more jitter, the less the correlation and the greater the movement. Therefore, the correlation (jitter) between the two lines can be determined from the motion. The example of FIG. 12 is based on this principle.
[0099]
Therefore, in the example of FIG. 12, the luminance signal (Y signal) is separated by the Y / C separation circuit 101 or the Y / C separation circuit 102, and this luminance signal is converted into the FIFO circuit 43 via the motion detection circuit 103 and the switch 92. (However, the luminance signal supplied from the Y / C separation circuit 101 to the FIFO circuit 43 is only the first line, and in the process of obtaining the correlation value of the second and subsequent lines, the jitter correction has already been performed. The processed luminance signal is the luminance signal from the Y / C separation circuit 102).
[0100]
Then, the motion detection circuit 103 detects the motion of the luminance signal input from the Y / C separation circuit 101 and the luminance signal one line before input from the FIFO circuit 43. This movement becomes larger when there is more jitter, and smaller when there is less jitter. Therefore, by outputting a coefficient corresponding to this movement (correlation) from the coefficient ROM 46, the same operation as described above can be realized. In this case, it goes without saying that the class determined when the coefficient set for each class stored in the coefficient ROM 46 is determined by the learning process is determined using the Y / C separation circuit and the motion detection circuit.
[0101]
In this way, the jitter included in the TV signal can be reduced without using the conventional TBC 1 having the structure shown in FIG.
[0102]
The time axis correction circuit 32 shown in FIG. 2 can be configured without using the write clock generation circuit (PLL) 13 as shown in FIG.
[0103]
In the above embodiment, the coefficient stored in the coefficient ROM 46 is obtained using the least square method, but the coefficient obtained using another method may be stored. Further, the present invention can be applied to a VCR and other electronic devices in addition to a TV receiver.
[0104]
Further, as described above, in the embodiment of the present invention, the class code is determined for a predetermined target pixel. However, the present invention is not limited to this, and the class code is determined for each predetermined block. You may make it do.
[0105]
Furthermore, although the embodiment of the present invention is realized by hardware using a block diagram, the present invention is not limited to this, and can also be realized by software using a CPU, a memory, or the like. .
[0106]
Note that as a transmission medium for transmitting a program for performing the processing as described above to a user, a communication medium such as a network or a satellite can be used in addition to a recording medium such as a magnetic disk, a CD-ROM, or a solid-state memory.
[0107]
Various modifications and application examples can be considered without departing from the gist of the present invention. Therefore, the gist of the present invention is not limited to the embodiment.
[0108]
【The invention's effect】
  As described above, the television signal processing device according to claim 1,Claim 10A television signal processing method according to claim 1, andClaim 11Described inrecoding mediaAccording to the above, based on the class code obtained by calculating the correlation value representing the correlation between the first scanning line and the second scanning line adjacent to the first scanning line, and quantizing the correlation value. The coefficient read out is applied to a linear primary operation with the input video signal to generate the television signal corresponding to a predetermined delay time.In the generation of the class code, the correlation value between the first carrier color signal of the first scanning line and the second carrier color signal of the second scanning line adjacent to the first scanning line is calculated. Since the calculation is performed using the first carrier color signal of the first scanning line of the video signal whose jitter has been corrected instead of the second carrier color signal of the second scanning line,Time axis fluctuations included in the television signal can be reliably corrected.
[0109]
  Also,Claim 12A television signal processing device according to claim 1,Claim 21A television signal processing method according to claim 1, andClaim 22Described inrecoding mediaAccording to the above, the coefficient read out based on the class code obtained by detecting the movement amount of the first scanning line and the second scanning line adjacent to the first scanning line is used as the input video signal. To generate the television signal corresponding to a predetermined delay time.In addition, in the generation of the class code, the motion amount is calculated using the first luminance signal of the first scanning line of the video signal subjected to jitter correction instead of the second luminance signal of the second scanning line. So thatTime axis fluctuations included in the television signal can be reliably corrected.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of an embodiment of a TV receiver 21 to which a television signal processing apparatus according to the present invention is applied.
2 is a block diagram showing a configuration of an embodiment of a time axis correction circuit 32 of FIG.
3 is a block diagram showing a configuration of an embodiment of a moving average correction circuit 41 in FIG. 2. FIG.
4 is a block diagram showing a configuration of an embodiment of the blocking circuit 47 of FIG. 2;
5 is a block diagram showing a configuration of an embodiment of the linear primary combined product-sum operation circuit 48 of FIG. 2;
6 is a flowchart for explaining the processing operation of the TV receiver 21 of FIG.
7 is a block diagram showing a configuration of an embodiment of an arithmetic unit 81 that generates a set of coefficients for each class stored in a coefficient ROM 46. FIG.
8 is a flowchart showing a processing operation for generating a set of coefficients for each class stored in the coefficient ROM 46. FIG.
FIG. 9 is a diagram illustrating a method for calculating a signal value corresponding to a target pixel of a predetermined line.
10 is a graph showing a TV signal corresponding to a predetermined scanning line, the jitter of which has been corrected by the time axis correction circuit 32 of FIG.
FIG. 11 is a block diagram showing a configuration of another embodiment of the time axis correction circuit 32 of FIG. 1;
12 is a block diagram showing a configuration of still another embodiment of the time axis correction circuit 32 of FIG. 1. FIG.
FIG. 13 is a graph showing a TV signal corresponding to a predetermined scanning line including jitter.
FIG. 14 is a block diagram showing a configuration of an example of a conventional TBC.
[Explanation of symbols]
1 TBC, 11 H / V sync separation circuit, 12 A / D conversion circuit, 13 write clock generation circuit, 14 memory, 15 write address counter, 16 D / A conversion circuit, 17 read address counter, 18 jump detection circuit, 19 Readout clock generation circuit, 21 TV receiver, 22 antenna, 31 tuner, 32 time axis correction circuit, 33 audio processing circuit, 34 video processing circuit, 35 speaker, 36 CRT, 41 moving average correction circuit, 42, 43 FIFO circuit, 44 correlation value calculation circuit, 45 quantization circuit, 46 coefficient ROM, 47 blocking circuit, 48 linear first product sum calculation circuit, 51 moving average calculation circuit, 52 delay circuit, 53 subtraction circuit, 54 addition circuit, 61-1 To 61-n delay element Child, 71-1 to 71-n multiplier circuit, 72 adder circuit, 73 limiter, 81 arithmetic unit, 82 digital VCR, 83 D / A converter, 84 VCR, 85 A / D converter circuit, 86 coefficient determining circuit, 91 movement Average correction circuit, 92 switches

Claims (22)

In a television signal processing apparatus that processes a television signal including a video signal composed of a plurality of scanning lines,
Extracting means for extracting a carrier color signal of a predetermined scanning line in a predetermined field of the video signal;
A class code that generates a class code based on the correlation between the first carrier color signal of the first scanning line and the second carrier color signal of the second scanning line adjacent to the first scanning line. Generating means;
Coefficient generating means for generating a set of coefficients corresponding to the class based on the class code;
Video signal generating means for generating a video signal subjected to jitter correction from the generated set of coefficients and the video signal ;
The class code generation means calculates a correlation value between a first carrier color signal of the first scanning line and a second carrier color signal of the second scanning line adjacent to the first scanning line. Computing means for
The calculation means is configured to output the first carrier color of the first scanning line of the jitter-corrected video signal generated by the video signal generation means instead of the second carrier color signal of the second scanning line. The correlation value is calculated using a signal
Television signal processing apparatus characterized by. The coefficient generating means includes
Storage means for storing a set of coefficients for each class;
The television signal processing apparatus according to claim 1, further comprising: a reading unit that reads out a set of coefficients corresponding to the class code based on the class code. The television signal processing apparatus according to claim 2, wherein the set of coefficients for each class is generated by learning in advance using at least a television signal for learning. The set of coefficients for each class is generated using a method of least squares based on a video signal of a television signal used by learning during a predetermined learning period. Television signal processing device. The class code generation means generates a class code for at least the target pixel,
The video signal generation means outputs the jitter-corrected video signal for at least the target pixel by linear primary combination of the generated set of coefficients and a plurality of pixels on a scanning line of a predetermined field including at least the target pixel. The television signal processing device according to claim 1, wherein the television signal processing device is generated. The class code generating means,
Quantizing means for quantizing the calculated correlation value and generating a quantized code as a class code
Television signal processing apparatus according to claim 1, characterized in that. The calculation means is configured to detect the first scan line of the first scan line of the jitter-corrected video signal generated by the video signal generation means with respect to the scan lines excluding the first scan line in a predetermined field of the video signal. The television signal processing apparatus according to claim 1 , wherein the correlation value is calculated using one carrier color signal. The extraction means subtracts the value of the video signal corresponding to a predetermined pixel of the plurality of pixels from the average value of the video signal corresponding to a predetermined number of consecutive pixels, thereby The television signal processing apparatus according to claim 1, wherein a signal is extracted. The television signal processing apparatus according to claim 1, wherein the second scanning line is a scanning line obtained by delaying the first scanning line by one line. In a television signal processing method for processing a television signal including a video signal composed of a plurality of scanning lines,
An extraction step of extracting a carrier color signal of a predetermined scanning line in a predetermined field of the video signal;
A class code that generates a class code based on the correlation between the first carrier color signal of the first scanning line and the second carrier color signal of the second scanning line adjacent to the first scanning line. Generation step;
A coefficient generation step for generating a set of coefficients corresponding to the class based on the class code;
A video signal generating step for generating a video signal subjected to jitter correction from the set of generated coefficients and the video signal;
Including
In the processing of the class code generation step, the correlation between the first carrier color signal of the first scanning line and the second carrier color signal of the second scanning line adjacent to the first scanning line. A value operation,
Instead of the second carrier color signal of the second scanning line, the first carrier color signal of the first scanning line of the jitter-corrected video signal generated by the processing of the video signal generation step is used. The correlation value was calculated
Television signal processing method characterized by. In a recording medium on which a program used for a television signal processing apparatus that processes a television signal including a video signal composed of a plurality of scanning lines is recorded ,
An extraction step of extracting a carrier color signal of a predetermined scanning line in a predetermined field of the video signal;
A class code that generates a class code based on the correlation between the first carrier color signal of the first scanning line and the second carrier color signal of the second scanning line adjacent to the first scanning line. Generation step;
A coefficient generation step for generating a set of coefficients corresponding to the class based on the class code;
A video signal generating step for generating a video signal subjected to jitter correction from the set of generated coefficients and the video signal;
Including
In the processing of the class code generation step, the correlation between the first carrier color signal of the first scanning line and the second carrier color signal of the second scanning line adjacent to the first scanning line. A value operation,
Instead of the second carrier color signal of the second scanning line, the first carrier color signal of the first scanning line of the jitter-corrected video signal generated by the processing of the video signal generation step is used. The correlation value was calculated
A recording medium characterized by the above. In a television signal processing apparatus that processes a television signal including a video signal composed of a plurality of scanning lines,
Extracting means for extracting a luminance signal of a predetermined scanning line of a predetermined field of the video signal;
A class code that generates a class code based on the amount of motion between the first luminance signal of the first scanning line and the second luminance signal of the second scanning line adjacent to the first scanning line. Generating means;
Coefficient generating means for generating a set of coefficients corresponding to the class based on the class code;
Video signal generating means for generating a video signal subjected to jitter correction from the generated set of coefficients and the video signal ;
The class code generation unit is configured to generate a first luminance of the first scanning line of the jitter-corrected video signal generated by the video signal generation unit, instead of the second luminance signal of the second scanning line. Calculate the amount of motion using a signal
Television signal processing apparatus characterized by. The coefficient generating means includes
Storage means for storing a set of coefficients for each class;
The television signal processing apparatus according to claim 12 , further comprising: a reading unit that reads out a set of coefficients corresponding to the class code based on the class code. The television signal processing apparatus according to claim 13 , wherein the set of coefficients for each class is generated in advance by learning using at least a television signal for learning. Set of coefficients for each of the classes, according to claim 14, characterized in that on the basis of a video signal of a television signal used by the learning in a predetermined learning period, are generated using the method of least squares Television signal processing device. The class code generation means generates a class code for at least the target pixel,
The video signal generation means outputs the jitter-corrected video signal for at least the target pixel by linear primary combination of the generated set of coefficients and a plurality of pixels on a scanning line of a predetermined field including at least the target pixel. The television signal processing device according to claim 12 , wherein the television signal processing device is generated. The class code generating means includes a first luminance signal of a first scanning line;
A detecting unit configured to detect a movement amount between a second luminance signal of a second scanning line adjacent to the first scanning line, and generating the class code based on the detected movement amount; The television signal processing apparatus according to claim 12 , wherein The television signal processing apparatus according to claim 12 , wherein the extraction unit includes a Y / C separation unit that extracts a luminance signal. The television signal processing apparatus according to claim 12 , wherein the second scanning line is a scanning line obtained by delaying the first scanning line by one line. The class code generation unit is configured to detect a first scan line of the jitter-corrected video signal generated by the video signal generation unit with respect to a scan line excluding a first scan line of a predetermined field of the video signal. The television signal processing apparatus according to claim 12 , wherein the movement is calculated using the first luminance signal. In a television signal processing method for processing a television signal including a video signal composed of a plurality of scanning lines,
An extraction step of extracting a luminance signal of a predetermined scanning line of a predetermined field of the video signal;
A class code that generates a class code based on the amount of motion between the first luminance signal of the first scanning line and the second luminance signal of the second scanning line adjacent to the first scanning line. Generation step;
A coefficient generation step for generating a set of coefficients corresponding to the class based on the class code;
A video signal generating step for generating a video signal subjected to jitter correction from the set of generated coefficients and the video signal;
Including
In the processing of the class code generation step, the first scanning line of the jitter-corrected video signal generated by the processing of the video signal generation step is used instead of the second luminance signal of the second scanning line. The amount of motion is calculated using the first luminance signal
Television signal processing method characterized by. In a recording medium on which a program used for a television signal processing apparatus that processes a television signal including a video signal composed of a plurality of scanning lines is recorded ,
An extraction step of extracting a luminance signal of a predetermined scanning line of a predetermined field of the video signal;
A class code that generates a class code based on the amount of motion between the first luminance signal of the first scanning line and the second luminance signal of the second scanning line adjacent to the first scanning line. Generation step;
A coefficient generation step for generating a set of coefficients corresponding to the class based on the class code;
A video signal generating step for generating a video signal subjected to jitter correction from the set of generated coefficients and the video signal;
Including
In the processing of the class code generation step, the first scanning line of the jitter-corrected video signal generated by the processing of the video signal generation step is used instead of the second luminance signal of the second scanning line. The amount of motion is calculated using the first luminance signal
A recording medium characterized by the above.

Images