JP4322448B2 - Digital camera and digital camera control method - Google Patents

Description

【００６９】
同表に示すように、タイミングジェネレータ４８は、合焦制御モード時には、垂直同期信号ＶＩの周期が、垂直同期信号ＶＤの周期ＶＤＳの１倍にオフセット値Ｎ１を加算した値以上となるように垂直同期信号ＶＩを生成し、スルー画像モード及び露出補正モード時には、垂直同期信号ＶＩの周期が、垂直同期信号ＶＤの周期ＶＤＳの２倍にオフセット値Ｎ２を加算した値以上となるように垂直同期信号ＶＩを生成する。ここで、垂直同期信号ＶＤの周期ＶＤＳに乗じた定数（合焦制御モード時の‘１’、スルー画像モード時及び露出補正モード時の‘２’）が本発明のＰに相当するものであり、動作モードに応じて予め定められた自然数である。
【００７０】
すなわち、合焦制御モードでは、高品質なデジタル画像データを得るよりも高速な制御が重視されるため、ＣＣＤ２２による撮像によって得られるデジタル画像データの垂直方向の間引き数を１／８間引きとするように、垂直同期信号ＶＩの周期を垂直同期信号ＶＤの周期ＶＤＳの１倍にオフセット値Ｎ１を加算したものとしている。これに対して、スルー画像モード及び露出補正モードでは、高速な制御よりも高品質なデジタル画像データを得ることが重視されるため、ＣＣＤ２２による撮像によって得られるデジタル画像データの垂直方向の間引き数を１／４間引きとするように、上記Ｐの値を合焦制御モードの場合の値より大きな‘２’として、垂直同期信号ＶＩの周期を垂直同期信号ＶＤの周期ＶＤＳの２倍にオフセット値Ｎ２を加算したものとしている。
【００７１】
ここで、上記オフセット値Ｎ１及びオフセット値Ｎ２は、周辺温度や湿度等の環境変化、水晶発振器８０及びセラミック発振器８２の機差等の各種誤差要因を考慮して、垂直同期信号ＶＤの周期ＶＤＳにＰの値を乗算して得られた値に加算することにより、垂直同期信号ＶＩの周期を、確実に周期ＶＤＳのＰ倍以上とすることができる値を適用する。
【００７２】
すなわち、各種誤差要因がない場合は、垂直同期信号ＶＩの周期ＶＩＳは、次の（１）式によって決定することができる。従って、このときの周期ＶＩＳとしては、図２に示される領域Ａ（同図の網点領域）の何れの値でも適用することができる。
【００７３】
ＶＩＳ≧Ｐ×ＶＤＳ ・・・（１）
しかしながら、実際には上記のような各種誤差要因があるため、本実施の形態では、周期ＶＩＳを、上記（１）式に対して各種誤差要因に基づいて決定したオフセット値Ｎを加算した、次の（２）式によって決定するようにしている。すなわち、本実施の形態では、図２に示される領域Ｂ（同図の斜線領域）の何れかの値を周期ＶＩＳとして適用するようにしている。
【００７４】
ＶＩＳ≧Ｐ×ＶＤＳ＋Ｎ ・・・（２）
なお、デジタルカメラ１０には、これら以外の種々の動作モードが用意されているが、ここでの説明は省略する。
【００７５】
タイミングジェネレータ４８は、撮像制御部６２から動作モードを示す情報をシリアル通信によって受信することができ、かつ受信した動作モードに応じた周期の垂直同期信号ＶＩを生成できるように構成されている。
【００７６】
ＣＣＤ２２が本発明の撮像手段に、セラミック発振器８２が本発明の第１の発振手段に、ビデオエンコーダ６６が本発明の第１の信号生成手段に、水晶発振器８０が本発明の第２の発振手段に、タイミングジェネレータ４８が本発明の第２の信号生成手段及びリセット手段に、各々相当する。
【００７７】
次に、本実施の形態に係るデジタルカメラ１０の作用を説明する。なお、ここでは、ＬＣＤ７２をファインダとして使用すると共に、ＣＣＤ２２による連続的な撮像によって得られたスルー画像をＬＣＤ２２に表示する場合について説明する。
【００７８】
デジタルカメラ１０の不図示の電源スイッチがオンされると、電源部８４より水晶発振器８０及びセラミック発振器８２に電源電力が供給されて水晶発振器８０及びセラミック発振器８２が各々作動を開始し、水晶発振器８０によって発生されたクロック信号のタイミングジェネレータ４８への供給が開始されると共に、セラミック発振器８２によって発生されたクロック信号のビデオエンコーダ６６への供給が開始される。なお、この各クロック信号のタイミングジェネレータ４８及びビデオエンコーダ６６への供給は、不図示の電源スイッチがオフされるまで継続して行なわれる。
【００７９】
ビデオエンコーダ６６では、セラミック発振器８２から入力されているクロック信号に基づいて垂直同期信号ＶＤ及び水平同期信号ＨＤを生成してＬＣＤ制御部６５に供給すると共に、撮像制御部６２を介してタイミングジェネレータ４８に供給する。なお、この垂直同期信号ＶＤ及び水平同期信号ＨＤのＬＣＤ制御部６５及びタイミングジェネレータ４８への供給も、不図示の電源スイッチがオフされるまで継続して行なわれる。
【００８０】
一方、タイミングジェネレータ４８では、水晶発振器８０から供給されているクロック信号に基づいて、垂直同期信号ＶＩ及び水平同期信号ＨＩの生成を開始する。なお、このとき、垂直同期信号ＶＩは、撮像制御部６２から受信されている動作モードを示す情報に基づき、表１に示したように、垂直同期信号ＶＤの周期ＶＤＳをＰ倍（Ｐは動作モードに応じて予め定められた自然数）した周期以上の周期となるように生成される。ここでは、上記動作モードを示す情報としてスルー画像モードを示す情報が撮像制御部６２から受信されているので、上記Ｐの値としては‘２’が適用される。
【００８１】
また、タイミングジェネレータ４８は、垂直同期信号ＶＩの生成動作に対し、撮像制御部６２から入力されている垂直同期信号ＶＤを基準として周期ＶＤＳをＰ倍した周期毎にリセットをかける。
【００８２】
図３には、上記Ｐの値が‘２’である場合の、すなわち動作モードがスルー画像モード又は露出補正モードである場合の垂直同期信号ＶＩ及び垂直同期信号ＶＤのタイムチャートが示されている。同図に示すように、この場合の垂直同期信号ＶＩの生成動作は、垂直同期信号ＶＤをトリガーとしてリセットがかけられるので、垂直同期信号ＶＩは、垂直同期信号ＶＤに確実に同期すると共に、正確に垂直同期信号ＶＤの周期の２倍の周期となるように生成される。
【００８３】
このとき、リセット前の垂直同期信号ＶＩは、垂直同期信号ＶＤの周期をＰ倍した周期以上の周期となるように生成されているので、図５を参照して説明したような、立て続けに２回ローレベルとなってしまう不具合の発生を未然に防止することができる。
【００８４】
タイミングジェネレータ４８によって生成された垂直同期信号ＶＩ及び水平同期信号ＨＩは垂直・水平ドライバ２４に継続的に出力され、垂直・水平ドライバ２４では、入力された垂直同期信号ＶＩ及び水平同期信号ＨＩに基づいてＣＣＤ２２を駆動するための駆動信号を生成してＣＣＤ２２に出力する。これによって、ＣＣＤ２２は、被写体像の撮像を開始し、当該撮像によって得られた信号の出力が開始される。
【００８５】
ＣＣＤ２２から出力された信号は、相関２重サンプリング回路４２によって相関２重サンプリング処理が施され、ゲインコントローラ４４によってＣＣＤ２２におけるＲ（赤）、Ｇ（緑）、Ｂ（青）毎の感度調整が施された後、各画素毎のＲ、Ｇ、Ｂ信号としてＡ／Ｄコンバータ４６に加えられる。Ａ／Ｄコンバータ４６は、ゲインコントローラ４４から順次加えられるＲ、Ｇ、Ｂ信号を各々１２ビットのＲ、Ｇ、Ｂ信号（デジタル画像データ）に変換して撮像制御部６２に出力する。
【００８６】
一方、タイミングジェネレータ４８によって生成された垂直同期信号ＶＩ及び水平同期信号ＨＩは撮像制御部６２にも出力される。
【００８７】
撮像制御部６２は、タイミングジェネレータ４８から入力された垂直同期信号ＶＩ及び水平同期信号ＨＩに基づいて、Ａ／Ｄコンバータ４６から順次入力されるデジタル画像データを、内蔵しているラインバッファに逐次蓄積すると共に、所定量のデジタル画像データがラインバッファに蓄積される度に、蓄積されたデジタル画像データをＳＤＲＡＭ７４に格納（転送）する。
【００８８】
ＳＤＲＡＭ７４に格納されたデジタル画像データは、ＣＰＵ６１によって読み出され、これらに光源種に応じたデジタルゲインをかけることでホワイトバランス調整を行なうと共に、ガンマ処理及びシャープネス処理を行なって８ビットのデジタル画像データを生成し、更にＹＣ信号処理して輝度信号Ｙとクロマ信号Ｃｒ、Ｃｂ（以下、「ＹＣ信号」という。）を生成し、ＹＣ信号を再びＳＤＲＡＭ７４に格納する。
【００８９】
ＬＣＤ制御部６５では、ＳＤＲＡＭ７４に格納されたＹＣ信号を順次読み出し、読み出したＹＣ信号によって示される画像を、ビデオエンコーダ６６から入力されている垂直同期信号ＶＤ及び水平同期信号ＨＤに基づいてＬＣＤ７２に表示するように制御する。
【００９０】
以上の動作によって、ＬＣＤ７２には被写体のスルー画像が逐次表示されることになる。
【００９１】
なお、以上の動作が行なわれている間に、撮像制御部６２は、合焦制御を行う所定のタイミングで合焦制御モードを示す情報をタイミングジェネレータ４８にシルアル通信により送信する。これによって、垂直同期信号ＶＩの周期は、合焦制御を行う際には、合焦制御に適した周期に切り替えられることになる。
【００９２】
一方、タイミングジェネレータ４８は、光学ユニット２０に備えられたシャッター及び絞りを駆動させるためのタイミング信号を生成してシャッタ・アイリスモータドライバ２６に出力する。シャッタ・アイリスモータドライバ２６では、入力されたタイミング信号に基づいて上記シャッター及び絞りが駆動されるように制御される。
【００９３】
なお、不図示のシャッターボタンが撮影者によって押圧操作された場合には、ＳＤＲＡＭ７４に格納されたＹＣ信号を、圧縮・伸張部６３によって所定の圧縮形式で圧縮した後にメディア制御部６４を介して記憶メディア７０に記憶する。
【００９４】
以上詳細に説明したように、本実施の形態に係るデジタルカメラ１０及びデジタルカメラの制御方法では、再生系と撮像系とで各々個別の発振器によってクロック信号を発生しているので、各系で共通のクロック信号を用いる場合のように分周するための回路を用いる必要がなく、この結果として低コストとすることができると共に、垂直同期信号ＶＩの周期を垂直同期信号ＶＤの周期のＰ倍以上としているので、撮像系及び再生系の各々の垂直同期信号の同期を安定してとることができる。
【００９５】
また、本実施の形態に係るデジタルカメラ１０及びデジタルカメラの制御方法では、垂直同期信号ＶＩを、垂直同期信号ＶＤの周期ＶＤＳをＰ倍した周期に所定のオフセット値Ｎを加算した周期以上の周期となるように生成しているので、オフセット値Ｎを加算しない場合に比較して、撮像系及び再生系の各々の垂直同期信号の同期を、より安定してとることができる。
【００９６】
また、本実施の形態に係るデジタルカメラ１０及びデジタルカメラの制御方法では、オフセット値Ｎを、セラミック発振器８２によって発生したクロック信号及び水晶発振器８０によって発生したクロック信号における各々の周期の環境変化に応じた誤差、及びセラミック発振器８２及び水晶発振器８０における各々の機差に応じた誤差の双方に基づいて、垂直同期信号ＶＩの周期が垂直同期信号ＶＤの周期のＰ倍以上となるように決定しているので、これらの誤差要因に起因する不具合の発生を未然に防止することができる。
【００９７】
更に、本実施の形態に係るデジタルカメラ１０及びデジタルカメラの制御方法では、合焦制御モードに対応するＰの値を、スルー画像モード及び露出補正モードに対応するＰの値より小さな値としているので、動作モードに応じて好適な周期とされた垂直同期信号ＶＩを生成することができる。
【００９８】
なお、本実施の形態では、図２に示したように、垂直同期信号ＶＩの周期ＶＩＳの下限値を垂直同期信号ＶＤの周期ＶＤＳに対して線形に求める場合について説明したが、本発明はこれに限定されるものではなく、垂直同期信号ＶＤの周期ＶＤＳをＰ倍した周期以上となるように求めることができる形態であれば、非線形に求める形態とすることもできる。この場合も、本実施の形態と同様の効果を奏することができる。
【００９９】
【発明の効果】
本発明に係るデジタルカメラ及びデジタルカメラの制御方法によれば、再生系と撮像系とで各々個別の発振手段によってクロック信号を発生しているので、各系で共通のクロック信号を用いる場合のように分周するための回路を用いる必要がなく、この結果として低コストとすることができると共に、撮像用垂直同期信号の周期を再生用垂直同期信号の周期のＰ倍よりも長い周期としているので、撮像系及び再生系の各々の垂直同期信号の同期を安定してとることができる、という効果が得られる。
【図面の簡単な説明】
【図１】実施の形態に係るデジタルカメラ１０の構成を示すブロック図である。
【図２】実施の形態に係る垂直同期信号ＶＩの周期の設定に関する説明に供するグラフである。
【図３】実施の形態に係るデジタルカメラ１０の作用の説明に供する図であり、撮像系の垂直同期信号ＶＩ及び再生系の垂直同期信号ＶＤのタイムチャートの一例である。
【図４】撮像系及び再生系の各々の垂直同期信号が同期している場合と、非同期の場合と、の各々のスルー画像再生時の動作の説明に供する概略図である。
【図５】請求項１記載の発明の説明に供する撮像系の垂直同期信号ＶＩ及び再生系の垂直同期信号ＶＤのタイムチャートの一例である。
【符号の説明】
１０ デジタルカメラ
２０ 光学ユニット
２２ ＣＣＤ（撮像手段）
４８ タイミングジェネレータ（第２の信号生成手段及びリセット手段）
６６ ビデオエンコーダ（第１の信号生成手段）
８０ 水晶発振器（第２の発振手段）
８２ セラミック発振器（第１の発振手段）[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a digital camera and a digital camera control method, and more particularly to a digital camera and a digital camera control method capable of reproducing an image obtained by photographing.
[0002]
[Prior art]
Conventionally, a through image (moving image) obtained by continuous imaging by an image sensor is electrically displayed (reproduced) on a finder (so-called electronic view finder) or a liquid crystal display having a wider display area than the finder. Digital cameras that can do this have been commercialized.
[0003]
In this type of digital camera, a system related to imaging with an image sensor (hereinafter referred to as “imaging system”) and a system related to reproduction of image data obtained by imaging with the image sensor (hereinafter referred to as “reproduction system”). In both cases, a horizontal synchronizing signal and a vertical synchronizing signal are required.
[0004]
At this time, it is preferable that the vertical synchronization signals of the imaging system and the reproduction system are synchronized. Hereinafter, this reason will be described.
[0005]
For example, when reproducing a through image obtained by continuous imaging by an image sensor, generally, image data indicated by a video signal for one screen showing the through image is temporarily stored in a predetermined memory space of a built-in memory. The image data is stored and read out from the memory and reproduced by a liquid crystal display (hereinafter referred to as “LCD”) or an electronic view finder (hereinafter referred to as “EVF”). Image data is stored in another memory space of the memory. Then, by repeating this operation alternately, smooth through image reproduction is realized. Therefore, the memory requires a memory space for at least two screens.
[0006]
Here, the respective operations of the case where the vertical synchronizing signals of the imaging system and the reproducing system are synchronized and the case of being asynchronous will be described with reference to FIG. In the figure, the vertical synchronization signal VI is an imaging system vertical synchronization signal, and the vertical synchronization signal VD is a reproduction system vertical synchronization signal.
[0007]
As shown in FIG. 4A, when the vertical synchronization signal VI and the vertical synchronization signal VD are synchronized, image data for one screen is taken in and a predetermined memory space in the memory (hereinafter referred to as “A plane”). The image data for the next screen is taken in and stored in another memory space in the memory (hereinafter referred to as “B surface”), and at the same time, the image stored on the A surface. A through image can be reproduced by alternately repeating the process of reading and reproducing data for the A and B planes.
[0008]
That is, reading the image data from the memory space in the middle of storing the image data for reproduction must be avoided because accurate image reproduction may not be performed, but each vertical synchronization signal VI, When the VD is synchronized, it is possible to continuously capture and reproduce image data without causing such a situation. Therefore, in this case, only the memory space for two screens of the A side and B side needs to exist in the memory, and the memory capacity for storing image data can be minimized.
[0009]
On the other hand, when the vertical synchronization signal VI and the vertical synchronization signal VD are asynchronous, as shown in FIG. 4B, the reproduction timing of the image data is the timing of storing the image data for the A plane, and B In some cases, the timing of storing image data for a surface may be straddled. For this reason, the image data stored in the A surface is read while the image data is stored in the A surface, or the image stored in the B surface while the image data is stored in the B surface. A situation in which data is read may occur.
[0010]
Therefore, in order to avoid this situation, a memory space for one screen (referred to as “C plane” in FIG. 4B) is further provided as a third memory space in the above memory. The image data stored on the remaining surface is reproduced at the reproduction timing across the other surface. Therefore, when the vertical synchronization signals of the imaging system and the reproduction system are asynchronous, a memory space for at least three screens is required, and a memory for storing image data is required compared to the case where the vertical synchronization signals are synchronized. It is necessary to increase the capacity.
[0011]
Thus, it can be said that it is advantageous that the vertical synchronization signals VI and VD of the imaging system and the reproduction system are synchronized in terms of the storage capacity of the memory that temporarily stores the image data.
[0012]
Therefore, as a technique for synchronizing between synchronization signals used in two different systems, Japanese Patent Laid-Open No. 6-276424 provides an image sensor and a drive circuit for the image sensor in a camera head, and camera control is performed by the drive circuit. A technique for generating horizontal and vertical drive pulses (corresponding to the above-mentioned “horizontal synchronizing signal and vertical synchronizing signal”) based on a reference clock (corresponding to the “clock signal” of the present invention) generated in the device is described. ing.
[0013]
On the other hand, Japanese Patent Laid-Open No. 5-75915 generates a horizontal synchronizing signal, a vertical synchronizing signal, and a frame signal for outputting a video signal in which a camera shake is corrected in a first synchronizing signal generating circuit from a frame memory. The vertical synchronizing signal and the frame signal as the synchronizing signal for driving the image sensor in the second synchronizing signal generating circuit use the vertical synchronizing signal and the frame signal generated by the first synchronizing signal generating circuit as they are, and the horizontal synchronizing signal Describes a technique in which a clock signal is periodically reset by a vertical synchronizing signal or a frame signal generated by the first synchronizing signal generating circuit.
[0014]
[Problems to be solved by the invention]
However, in the technique described in Japanese Patent Laid-Open No. Hei 6-276424, the vertical synchronization signal and the horizontal synchronization signal used in different systems are generated by using a common clock signal, so that the cost is increased. was there.
[0015]
This is because, when a synchronization signal used in different systems is generated using a common clock signal, the clock signals are divided by different frequencies in order to generate a synchronization signal having a suitable period for each system. This is because it is necessary to use a plurality of expensive circuits such as a clock generator for the frequency division.
[0016]
On the other hand, in the technique described in the above Japanese Patent Application Laid-Open No. 5-75915, the vertical synchronization signal used in different systems is made common, so this is applied to an apparatus in which the period of the vertical synchronization signal is different for each system. However, in order to apply to such a device, a circuit for frequency division is required in the same manner as described above, and in this case, there is a problem that the cost increases.
[0017]
The present invention has been made to solve the above problems, and provides a digital camera capable of synchronizing the vertical synchronization signals of the imaging system and the reproduction system at a low cost, and a control method for the digital camera. For the purpose.
[0018]
[Means for Solving the Problems]
In order to achieve the above object, the digital camera according to claim 1 includes an imaging unit for imaging a subject, It becomes the standard of operation of the reproduction system First oscillation means for generating a first clock signal having a predetermined period, and a reproduction vertical synchronizing signal having a predetermined first period relating to reproduction of image data obtained by imaging by the imaging means, First signal generating means for generating the first clock signal based on the first clock signal, and having a period different from that of the first clock signal. It becomes the standard of the operation of the imaging system Second oscillation means for generating a second clock signal, and a second period obtained by multiplying the first period by P (P is a natural number determined in advance according to the operation mode). Longer than An imaging vertical synchronization signal related to imaging by the imaging means with a period is generated based on the second clock signal Configured to generate the imaging vertical synchronization signal by resetting the imaging vertical synchronization signal generation operation every second period with the reproduction vertical synchronization signal as a reference. A vertical synchronization signal is synchronized with the reproduction vertical synchronization signal in the second period. Second signal generating means; , It has.
[0019]
According to the digital camera of claim 1, It becomes the standard of operation of the reproduction system A first clock signal having a predetermined period is generated by the first oscillating means, and a reproduction vertical synchronizing signal having a predetermined first period relating to reproduction of image data obtained by imaging by the imaging means for imaging the subject is obtained. Generated by the first signal generating means based on the first clock signal. Here, the reproduction vertical synchronization signal corresponds to the reproduction-related vertical synchronization signal VD.
[0020]
The imaging means includes an imaging element such as a charge coupled device (CCD) or a complementary metal oxide semiconductor (CMOS) image sensor. The first oscillating means includes a crystal oscillator, a ceramic oscillator, and the like.
[0021]
In the digital camera according to claim 1, the digital camera has a period different from that of the first clock signal. It becomes the standard of the operation of the imaging system A second clock signal is generated by the second oscillating means, and a second period obtained by multiplying the first period by P times (P is a natural number predetermined according to the operation mode). Longer than An imaging vertical synchronization signal related to imaging by the imaging means with a period is generated based on the second clock signal. By second signal generating means configured to: Generation operation of the vertical synchronizing signal for imaging by the second signal generating means for each second period on the basis of the vertical synchronizing signal for reproduction Is Set As a result, the imaging vertical synchronization signal is generated, and the imaging vertical synchronization signal is synchronized with the reproduction vertical synchronization signal in the second period. . The imaging vertical synchronization signal corresponds to the imaging system vertical synchronization signal VI described above.
[0022]
Here, the period of the vertical synchronizing signal for imaging is P times the period of the vertical synchronizing signal for reproduction. Longer than the specified period The reason for this will be explained. Here, the vertical synchronizing signal for reproduction is described as a vertical synchronizing signal VD, and the vertical synchronizing signal for imaging is described as a vertical synchronizing signal VI.
[0023]
For example, when the value of P is “2”, the vertical synchronization signal VI is reset by the reset means every two times the period of the vertical synchronization signal VD with reference to the vertical synchronization signal VD. At this time, when the period of the vertical synchronizing signal VI is less than twice the period of the vertical synchronizing signal VD, as shown in FIG. 5 as an example, the vertical synchronizing signal VI once becomes a low level and then becomes a high level. After that, there is a case where it becomes low level again by reset.
[0024]
As described above, when the signal level becomes low level twice in succession, there is a possibility that the control in the case of performing the control according to the vertical synchronization signal VI may be broken. In order to prevent the occurrence of such a problem, in the present invention, the period of the vertical synchronizing signal for imaging is set to P times the period of the vertical synchronizing signal for reproduction. Longer than the specified period It is.
[0025]
The second oscillating means includes a crystal oscillator, a ceramic oscillator, and the like.
[0026]
Thus, according to the digital camera of the first aspect, since the clock signal is generated by the individual oscillation means in the reproduction system and the imaging system, as in the case where a common clock signal is used in each system. Therefore, it is not necessary to use a circuit for frequency division, and as a result, the cost can be reduced and the period of the vertical synchronizing signal for imaging is P times the period of the vertical synchronizing signal for reproduction. Longer than the specified period Therefore, it is possible to stably synchronize the vertical synchronization signals of the imaging system and the reproduction system.
[0027]
By the way, the period of each of the first clock signal and the second clock signal generated by the first oscillating means and the second oscillating means of the present invention is different from the design value due to various error factors. It may become a thing. Therefore, as in the present invention, the period of the vertical synchronizing signal for imaging is P times the period of the vertical synchronizing signal for reproduction. Longer than the specified period Even if designed so that, in practice, the period of the imaging vertical synchronization signal may be less than P times that of the reproduction vertical synchronization signal.
[0028]
In view of this, the invention according to claim 2 is the invention according to claim 1, wherein the second signal generation unit sets the imaging vertical synchronization signal to a predetermined offset value in the second period. It generates so that it may become a period more than the period added.
[0029]
According to the digital camera of the second aspect, the second signal generation unit generates the imaging vertical synchronization signal so as to have a period equal to or longer than a period obtained by adding a predetermined offset value to the second period. The Note that the offset value at this time is added to the second period in consideration of various error factors, so that the period of the vertical synchronizing signal for imaging is surely P times the first period. Longer than the specified period As values that can be obtained, values obtained by experiments or computer simulations can be applied.
[0030]
Thus, according to the digital camera of the second aspect, the same effect as that of the first aspect of the invention can be achieved, and the vertical synchronization signal for imaging is set to a predetermined offset value in the second period. Since they are generated so as to have a period equal to or greater than the added period, the vertical synchronization signals of the imaging system and the reproduction system can be more stably synchronized.
[0031]
By the way, it is assumed that most of the error factors of the periods of the first clock signal and the second clock signal in the present invention are environmental changes such as ambient temperature and humidity, and the first oscillation means and the second oscillation. The difference of means is mentioned.
[0032]
Therefore, a digital camera according to a third aspect is the digital camera according to the second aspect, wherein the offset value is an error corresponding to an environmental change of each period in the first clock signal and the second clock signal, and The period of the imaging vertical synchronization signal is P times the first period based on at least one of the errors according to the difference between the first oscillating means and the second oscillating means. Longer than It was decided to become.
[0033]
According to the digital camera of claim 3, the offset value of the present invention includes an error according to an environmental change of each period in the first clock signal and the second clock signal, and the first oscillation. The period of the vertical synchronizing signal for imaging is P times the first period based on at least one of the errors corresponding to each machine difference in the first oscillation means and the second oscillation means Longer than To be determined.
[0034]
Thus, according to the digital camera of the third aspect, the same effect as that of the second aspect of the invention can be achieved, and the offset value in the second aspect of the invention can be obtained by using the first clock signal and An imaging vertical synchronization signal based on at least one of an error according to an environmental change in each cycle in the second clock signal and an error according to each machine difference in the first oscillation means and the second oscillation means. Period is P times the first period Longer than Therefore, it is possible to prevent the occurrence of defects due to these error factors.
[0035]
By the way, the vertical synchronizing signal for imaging according to the present invention can be used so as to switch the thinning number in the vertical direction of image data obtained by imaging by the imaging means according to the period. More specifically, the number of thinning-out can be increased as the period of the imaging vertical synchronization signal is increased.
[0036]
On the other hand, when performing focus control (so-called autofocus control) in a so-called TTL (Through The Lens) method in which the position of a lens is set in a digital camera so that the contrast of the read image is maximized, Since such high-definition image data is not required and high-speed processing is required, it is preferable that the period of the imaging vertical synchronization signal at this time be relatively small.
[0037]
Also, when reproducing a through image obtained by continuous imaging by an imaging means in a digital camera, or when performing exposure correction based on image data obtained by imaging, a high-quality through image is reproduced. In addition, since high-definition image data is required for highly accurate exposure correction, it is preferable that the period of the imaging vertical synchronization signal at this time be relatively large.
[0038]
Therefore, a digital camera according to a fourth aspect is the invention according to any one of the first to third aspects, wherein the operation mode is a focus control mode which is a mode for performing focus control, and the imaging means. The P value corresponding to the focus control mode is provided with a through image mode that is a mode for reproducing a through image obtained by continuous imaging, and an exposure correction mode that is a mode for performing exposure correction. Is a value smaller than the value of P corresponding to the through image mode and the exposure correction mode. Thus, it is possible to generate an imaging vertical synchronization signal having a suitable period according to the operation mode.
[0039]
On the other hand, the control method of the digital camera according to claim 5 is an imaging means for imaging a subject, It becomes the standard of operation of the reproduction system First oscillating means for generating a first clock signal having a predetermined period, and a period different from that of the first clock signal; It becomes the standard of the operation of the imaging system A method for controlling a digital camera including a second oscillating means for generating a second clock signal, for reproducing a predetermined first period relating to reproduction of image data obtained by imaging by the imaging means. Generate vertical synchronization signal based on the first clock signal And A second period obtained by multiplying the first period by P (P is a natural number determined in advance according to the operation mode) Longer than A vertical synchronization signal for imaging related to imaging by the imaging means with a period is generated based on the second clock signal Configured to The operation of generating the imaging vertical synchronization signal by the second signal generation means is reset every second period with the reproduction vertical synchronization signal as a reference. Thus, the imaging vertical synchronization signal is generated, and the imaging vertical synchronization signal is synchronized with the reproduction vertical synchronization signal in the second period. Is.
[0040]
Therefore, according to the control method of the digital camera described in claim 5, since it operates in the same manner as in the invention described in claim 1, each of the imaging system and the reproduction system is low-cost as in the invention described in claim 1. The vertical synchronization signal can be stably synchronized.
[0041]
According to a sixth aspect of the present invention, in the digital camera control method according to the fifth aspect of the present invention, the imaging vertical synchronization signal has a period equal to or longer than a period obtained by adding a predetermined offset value to the second period. Is generated.
[0042]
Therefore, according to the control method of the digital camera according to the sixth aspect, the same effect as the invention according to the fifth aspect can be obtained and the same effect as the invention according to the second aspect can be obtained. Similar to the described invention, the vertical synchronization signals of the imaging system and the reproduction system can be more stably synchronized.
[0043]
According to a seventh aspect of the present invention, in the digital camera control method according to the sixth aspect of the present invention, the offset value is determined according to an environmental change of each period of the first clock signal and the second clock signal. Based on at least one of an error and an error corresponding to each machine difference in the first oscillating means and the second oscillating means, the period of the imaging vertical synchronization signal is P times the first period. Longer than It was decided to become.
[0044]
Therefore, according to the control method of the digital camera of the seventh aspect, the same effect as the invention of the sixth aspect can be obtained and the same effect as the invention of the third aspect can be obtained. Similarly to the described invention, the first clock signal and the second clock signal according to the error according to the environmental change of each period, and the difference between the first oscillation means and the second oscillation means. It is possible to prevent the occurrence of a problem due to at least one error factor.
[0045]
Furthermore, a control method for a digital camera according to an eighth aspect of the present invention is the method according to any one of the fifth to seventh aspects, wherein the digital camera is a mode for performing focus control as the operation mode. The focus control mode includes a focus control mode, a through image mode that is a mode for reproducing a through image obtained by continuous imaging by the imaging unit, and an exposure correction mode that is a mode for performing exposure correction. The value of P corresponding to the mode is set to a value smaller than the value of P corresponding to the through image mode and the exposure correction mode.
[0046]
Therefore, according to the digital camera control method of the eighth aspect, the same effect as that of any one of the fifth to seventh aspects can be achieved, and the invention of the fourth aspect can be achieved. Since the operation is the same, it is possible to generate an imaging vertical synchronization signal having a suitable period according to the operation mode, as in the fourth aspect of the invention.
[0047]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. First, the configuration of the digital camera 10 according to the present embodiment will be described with reference to FIG.
[0048]
As shown in the figure, the digital camera 10 according to the present embodiment includes an optical unit 20 including a lens for forming a subject image, and a CCD 22 disposed behind the optical axis of the lens. And a signal processing unit 40 that generates digital image data representing a subject image based on an output signal from the CCD 22 and generates a timing signal for driving each unit of the optical unit 20, the CCD 22, and the like. Main controller 60 for controlling various operations, vertical / horizontal driver 24 for driving CCD 22, shutter / iris motor driver 26 for driving shutter and iris included in optical unit 20, and focus adjustment motor included in optical unit 20 A focus motor driver 28 for driving the zoom motor and a zoom motor included in the optical unit 20 That a zoom motor driver 30 is configured to include a.
[0049]
Note that the signal processing unit 40 and the main control unit 60 are configured as a one-chip LSI (Large Scale Integrated circuit), thereby reducing the size, high reliability, and cost of the digital camera 10. .
[0050]
In addition, the digital camera 10 includes an LCD 72 that displays a subject image and various information obtained by imaging with the CCD 22, an SDRAM (Synchronous Dynamic Random Access Memory) 74 that mainly stores digital image data obtained by imaging with the CCD 22, A flash ROM (Read Only Memory) 76 that stores various parameters, programs, and the like, and a ceramic oscillator that generates a clock signal of a predetermined frequency (24 MHz in the present embodiment) that serves as a reference for the operation of the reproduction system in the main control unit 60 82 and a power supply unit 84 that supplies power to the main control unit 60.
[0051]
On the other hand, the signal processing unit 40 includes a correlated double sampling circuit 42, a gain controller 44, an A / D converter 46, and a timing generator 48.
[0052]
The digital camera 10 generates a clock signal having a predetermined frequency (33 MHz in the present embodiment) that serves as a reference for the operation of the imaging system, and receives power from the power supply unit 84 via the main control unit 60. A supplied crystal oscillator 80 is provided.
[0053]
The main control unit 60 includes a central processing unit (CPU) 61 that controls the operation of the main control unit 60, an imaging control unit 62 that includes a line buffer having a predetermined capacity, and a predetermined compression format (the present embodiment). A compression / decompression unit 63 that compresses digital image data in JPEG (Joint Photographic Experts Group) format and decompresses the compressed digital image data as necessary, and a media control unit 64, an LCD controller 65, and a video encoder 66 are connected to each other via a bus BUS.
[0054]
A portable storage medium 70 such as a smart media, an IC card, a CD-R (Compact Disc-Recordable), a CD-RW (Compact Disc-ReWritable) is connected to the media control unit 64. Writing of various information to the storage medium 70 and reading of various information written on the storage medium 70 are controlled. An LCD 72 is connected to the LCD controller 65, and various information is displayed on the LCD 72 under the control of the LCD controller 65.
[0055]
The video encoder 66 is connected to a D / A converter 67 configured such that an EVF (not shown) can be connected. The video encoder 66 and the D / A converter 67 allow the EVF to be supplied to the D / A converter 67. The image data indicating the video to be displayed on the EVF when connected is converted into an NTSC color composite video signal and output to the EVF.
[0056]
In the video encoder 66, the ceramic oscillator 82 generates a vertical synchronizing signal VD that is a vertical synchronizing signal and a horizontal synchronizing signal HD that is a horizontal synchronizing signal when an image is displayed on the EVF or the LCD 72. Is generated based on the clock signal thus generated, and is used when the video encoder 66 itself displays an image on the EVF, and is transmitted to the LCD controller 65 via the bus BUS. The LCD controller 65 controls the display of video on the LCD 72 using the received vertical synchronization signal VD and horizontal synchronization signal HD.
[0057]
The LCD 72 and the EVF can display a moving image (through image) obtained by continuous imaging by the CCD 22 and can be used as a finder.
[0058]
The SDRAM 74 and the flash ROM 76 are connected to the bus BUS of the main control unit 60. Therefore, the CPU 61 can arbitrarily access the SDRAM 74 and the flash ROM 76.
[0059]
On the other hand, the output terminal of the CCD 22 is connected to the imaging control unit 62 via a correlated double sampling circuit 42, a gain controller 44, and an A / D converter 46 in this order.
[0060]
The timing generator 48 is connected to the vertical / horizontal driver 24, the shutter / iris motor driver 26, and the imaging control unit 62. Note that the timing generator 48 is configured such that the vertical synchronization signal VD and the horizontal synchronization signal HD generated by the video encoder 66 are input via the bus BUS and the imaging control unit 62 in this order.
[0061]
The timing generator 48 uses a vertical synchronizing signal VI that is a vertical synchronizing signal and a horizontal synchronizing signal HI that is a horizontal synchronizing signal of a system related to imaging by the CCD 22 (imaging system) as a clock signal generated by the crystal oscillator 80. And generated and output to the vertical / horizontal driver 24 and the imaging control unit 62.
[0062]
The input terminals of the focus motor driver 28 and the zoom motor driver 30 are connected to the main control unit 60 (more specifically, the CPU 61), and the output terminal of the focus motor driver 28 is connected to a focus adjustment motor provided in the optical unit 20. The output terminal of the zoom motor driver 30 is connected to a zoom motor provided in the optical unit 20.
[0063]
The lens included in the optical unit 20 according to the present embodiment has a plurality of lenses, is configured as a zoom lens that can change (magnify) the focal length, and includes a lens driving mechanism (not shown). . The lens driving mechanism includes a zoom motor and a focus adjustment motor, and the zoom motor and the focus adjustment motor are driven by drive signals supplied from the zoom motor driver 30 and the focus motor driver 28 under the control of the CPU 61, respectively. .
[0064]
When changing the optical zoom magnification, the CPU 61 drives and controls the zoom motor to change the focal length of the lens included in the optical unit 20.
[0065]
Further, the CPU 61 performs focus control by driving and controlling the focus adjustment motor so that the contrast of the image obtained by the imaging by the CCD 22 is maximized. That is, the digital camera 10 according to the present embodiment employs a so-called TTL system in which the lens position is set so that the contrast of the read image is maximized as the focus control, and the autofocus frame When the subject is located at the shooting position indicated by (2), the focus control is automatically performed by half-pressing a shutter button (not shown).
[0066]
By the way, in the digital camera 10, as an operation mode according to the shooting sequence, a focus control mode that is a mode for performing focus control, and a mode in which a through image of a subject obtained by continuous imaging by the CCD 22 is displayed on the LCD 72. A through image mode, and an exposure correction mode, which is a mode for performing exposure correction, are provided in advance.
[0067]
Table 1 shows the relationship between the vertical synchronizing signal VI of the imaging system and the vertical synchronizing signal VD of the reproduction system in each of the focus control mode, the through image mode, and the exposure correction mode of the digital camera 10 according to the present embodiment. , And the thinning number in the vertical direction of the digital image data obtained by imaging by the CCD 22 is shown.
[0068]
[Table 1]

[0069]
As shown in the table, in the focus control mode, the timing generator 48 is vertical so that the period of the vertical synchronization signal VI is equal to or greater than the value obtained by adding the offset value N1 to one period VDS of the vertical synchronization signal VD. The synchronization signal VI is generated, and in the through image mode and the exposure correction mode, the vertical synchronization signal VI has a period equal to or greater than a value obtained by adding the offset value N2 to twice the period VDS of the vertical synchronization signal VD. Generate VI. Here, a constant ('1' in the focus control mode, '2' in the through image mode and the exposure correction mode) multiplied by the cycle VDS of the vertical synchronization signal VD corresponds to P of the present invention. The natural number determined in advance according to the operation mode.
[0070]
That is, in the focus control mode, since high-speed control is more important than obtaining high-quality digital image data, the thinning-out number in the vertical direction of the digital image data obtained by imaging by the CCD 22 is reduced to 1/8. In addition, the offset value N1 is added to the cycle of the vertical synchronization signal VI to one time the cycle VDS of the vertical synchronization signal VD. On the other hand, in the through image mode and the exposure correction mode, since it is important to obtain high quality digital image data rather than high speed control, the thinning out number in the vertical direction of the digital image data obtained by the imaging by the CCD 22 is set. The value of P is set to '2' larger than the value in the focus control mode so as to make 1/4 thinning out, and the cycle of the vertical synchronization signal VI is set to twice the cycle VDS of the vertical synchronization signal VD. Is added.
[0071]
Here, the offset value N1 and the offset value N2 are set to the cycle VDS of the vertical synchronization signal VD in consideration of various error factors such as environmental changes such as ambient temperature and humidity, and machine differences of the crystal oscillator 80 and the ceramic oscillator 82. By adding to the value obtained by multiplying the value of P, a value that can reliably make the period of the vertical synchronization signal VI equal to or more than P times the period VDS is applied.
[0072]
That is, when there are no various error factors, the cycle VIS of the vertical synchronization signal VI can be determined by the following equation (1). Accordingly, any value in the region A (halftone dot region in FIG. 2) shown in FIG. 2 can be applied as the cycle VIS at this time.
[0073]
VIS ≧ P × VDS (1)
However, since there are actually various error factors as described above, in the present embodiment, the period VIS is calculated by adding the offset value N determined based on the various error factors to the above equation (1). (2) is determined. That is, in the present embodiment, any value in the area B (shaded area in FIG. 2) shown in FIG. 2 is applied as the cycle VIS.
[0074]
VIS ≧ P × VDS + N (2)
The digital camera 10 is provided with various operation modes other than these, but description thereof is omitted here.
[0075]
The timing generator 48 is configured to be able to receive information indicating the operation mode from the imaging control unit 62 by serial communication, and to generate a vertical synchronization signal VI having a period corresponding to the received operation mode.
[0076]
The CCD 22 is the imaging means of the present invention, the ceramic oscillator 82 is the first oscillation means of the present invention, the video encoder 66 is the first signal generation means of the present invention, and the crystal oscillator 80 is the second oscillation means of the present invention. The timing generator 48 corresponds to the second signal generating means and the resetting means of the present invention.
[0077]
Next, the operation of the digital camera 10 according to the present embodiment will be described. Here, a case will be described in which the LCD 72 is used as a viewfinder and a through image obtained by continuous imaging by the CCD 22 is displayed on the LCD 22.
[0078]
When a power switch (not shown) of the digital camera 10 is turned on, power is supplied from the power supply unit 84 to the crystal oscillator 80 and the ceramic oscillator 82, and the crystal oscillator 80 and the ceramic oscillator 82 start to operate. Is started to be supplied to the timing generator 48, and the clock signal generated by the ceramic oscillator 82 is started to be supplied to the video encoder 66. The supply of each clock signal to the timing generator 48 and the video encoder 66 is continued until a power switch (not shown) is turned off.
[0079]
In the video encoder 66, the vertical synchronization signal VD and the horizontal synchronization signal HD are generated based on the clock signal input from the ceramic oscillator 82 and supplied to the LCD control unit 65, and the timing generator 48 is connected via the imaging control unit 62. To supply. The supply of the vertical synchronizing signal VD and the horizontal synchronizing signal HD to the LCD control unit 65 and the timing generator 48 is continued until the power switch (not shown) is turned off.
[0080]
On the other hand, the timing generator 48 starts generating the vertical synchronization signal VI and the horizontal synchronization signal HI based on the clock signal supplied from the crystal oscillator 80. At this time, the vertical synchronization signal VI is P times the period VDS of the vertical synchronization signal VD based on the information indicating the operation mode received from the imaging control unit 62 (P is the operation). It is generated so as to have a period equal to or greater than a period that is a natural number determined in advance according to the mode. Here, since information indicating the through image mode is received from the imaging control unit 62 as information indicating the operation mode, “2” is applied as the value of P.
[0081]
In addition, the timing generator 48 resets the generation operation of the vertical synchronization signal VI every cycle obtained by multiplying the cycle VDS by P with reference to the vertical synchronization signal VD input from the imaging control unit 62.
[0082]
FIG. 3 shows a time chart of the vertical synchronization signal VI and the vertical synchronization signal VD when the value of P is “2”, that is, when the operation mode is the through image mode or the exposure correction mode. . As shown in the figure, since the generation operation of the vertical synchronizing signal VI in this case is reset by using the vertical synchronizing signal VD as a trigger, the vertical synchronizing signal VI is surely synchronized with the vertical synchronizing signal VD and is accurate. Are generated so as to have a cycle twice as long as that of the vertical synchronizing signal VD.
[0083]
At this time, the vertical synchronization signal VI before reset is generated so as to have a period equal to or more than a period obtained by multiplying the period of the vertical synchronization signal VD by P, so that 2 as described with reference to FIG. It is possible to prevent the occurrence of a problem that becomes a low level once.
[0084]
The vertical synchronization signal VI and the horizontal synchronization signal HI generated by the timing generator 48 are continuously output to the vertical / horizontal driver 24, and the vertical / horizontal driver 24 is based on the input vertical synchronization signal VI and horizontal synchronization signal HI. Then, a drive signal for driving the CCD 22 is generated and output to the CCD 22. As a result, the CCD 22 starts capturing the subject image and starts outputting the signal obtained by the imaging.
[0085]
The signal output from the CCD 22 is subjected to correlated double sampling processing by the correlated double sampling circuit 42, and the gain controller 44 performs sensitivity adjustment for each of R (red), G (green), and B (blue) in the CCD 22. After that, it is added to the A / D converter 46 as R, G and B signals for each pixel. The A / D converter 46 converts the R, G, and B signals sequentially applied from the gain controller 44 into 12-bit R, G, and B signals (digital image data) and outputs the signals to the imaging control unit 62.
[0086]
On the other hand, the vertical synchronization signal VI and the horizontal synchronization signal HI generated by the timing generator 48 are also output to the imaging control unit 62.
[0087]
The imaging control unit 62 sequentially stores digital image data sequentially input from the A / D converter 46 in the built-in line buffer based on the vertical synchronization signal VI and the horizontal synchronization signal HI input from the timing generator 48. In addition, each time a predetermined amount of digital image data is accumulated in the line buffer, the accumulated digital image data is stored (transferred) in the SDRAM 74.
[0088]
The digital image data stored in the SDRAM 74 is read out by the CPU 61, and white balance adjustment is performed by applying a digital gain corresponding to the light source type to the digital image data, and gamma processing and sharpness processing are performed to obtain 8-bit digital image data. Are further processed to generate a luminance signal Y and chroma signals Cr and Cb (hereinafter referred to as “YC signal”), and the YC signal is stored in the SDRAM 74 again.
[0089]
The LCD control unit 65 sequentially reads the YC signal stored in the SDRAM 74 and displays the image indicated by the read YC signal on the LCD 72 based on the vertical synchronization signal VD and the horizontal synchronization signal HD input from the video encoder 66. Control to do.
[0090]
Through the above operation, the through image of the subject is sequentially displayed on the LCD 72.
[0091]
Note that while the above operation is performed, the imaging control unit 62 transmits information indicating the focus control mode to the timing generator 48 by serial communication at a predetermined timing for performing focus control. As a result, the period of the vertical synchronization signal VI is switched to a period suitable for focus control when performing focus control.
[0092]
On the other hand, the timing generator 48 generates a timing signal for driving a shutter and an aperture provided in the optical unit 20 and outputs the timing signal to the shutter / iris motor driver 26. The shutter / iris motor driver 26 is controlled so as to drive the shutter and the aperture based on the input timing signal.
[0093]
When a shutter button (not shown) is pressed by the photographer, the YC signal stored in the SDRAM 74 is compressed in a predetermined compression format by the compression / expansion unit 63 and then stored via the media control unit 64. Store in media 70.
[0094]
As described above in detail, in the digital camera 10 and the digital camera control method according to the present embodiment, the clock signal is generated by the individual oscillators in the reproduction system and the imaging system. Therefore, it is not necessary to use a circuit for frequency division as in the case of using the clock signal, and as a result, the cost can be reduced, and the period of the vertical synchronizing signal VI is P times the period of the vertical synchronizing signal VD or more. Therefore, it is possible to stably synchronize the vertical synchronization signals of the imaging system and the reproduction system.
[0095]
In the digital camera 10 and the digital camera control method according to the present embodiment, the vertical synchronization signal VI has a period equal to or longer than a period obtained by adding a predetermined offset value N to a period obtained by multiplying the period VDS of the vertical synchronization signal VD by P. Therefore, the vertical synchronization signals of the imaging system and the reproduction system can be more stably synchronized as compared with the case where the offset value N is not added.
[0096]
In the digital camera 10 and the digital camera control method according to the present embodiment, the offset value N is determined according to the environmental change of each period in the clock signal generated by the ceramic oscillator 82 and the clock signal generated by the crystal oscillator 80. And the period of the vertical synchronizing signal VI is determined to be P times or more of the period of the vertical synchronizing signal VD based on both the error and the error corresponding to each machine difference in the ceramic oscillator 82 and the crystal oscillator 80. Therefore, it is possible to prevent the occurrence of defects due to these error factors.
[0097]
Furthermore, in the digital camera 10 and the digital camera control method according to the present embodiment, the value of P corresponding to the focus control mode is set to a value smaller than the value of P corresponding to the through image mode and the exposure correction mode. Thus, it is possible to generate the vertical synchronization signal VI having a suitable period according to the operation mode.
[0098]
In the present embodiment, as shown in FIG. 2, a case has been described in which the lower limit value of the cycle VIS of the vertical synchronization signal VI is obtained linearly with respect to the cycle VDS of the vertical synchronization signal VD. However, the present invention is not limited to this, and may be a non-linear form as long as it can be obtained so that the period VDS of the vertical synchronization signal VD is equal to or greater than P. Also in this case, the same effects as in the present embodiment can be obtained.
[0099]
【The invention's effect】
According to the digital camera and the control method of the digital camera according to the present invention, the clock signal is generated by the individual oscillation means in the reproduction system and the imaging system, so that a common clock signal is used in each system. Therefore, it is possible to reduce the cost, and the period of the imaging vertical synchronization signal is P times the period of the reproduction vertical synchronization signal. Longer cycle Therefore, it is possible to obtain an effect that the vertical synchronization signals of the imaging system and the reproduction system can be stably synchronized.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of a digital camera 10 according to an embodiment.
FIG. 2 is a graph for explaining the setting of the period of the vertical synchronization signal VI according to the embodiment;
FIG. 3 is a diagram for explaining the operation of the digital camera 10 according to the embodiment, and is an example of a time chart of an imaging system vertical synchronization signal VI and a reproduction system vertical synchronization signal VD;
FIGS. 4A and 4B are schematic diagrams for explaining operations when reproducing through images in the case where the vertical synchronization signals of the imaging system and the reproduction system are synchronized and in the case of being asynchronous. FIGS.
FIG. 5 is an example of a time chart of an imaging system vertical synchronization signal VI and a reproduction system vertical synchronization signal VD for explaining the invention according to claim 1;
[Explanation of symbols]
10 Digital camera
20 Optical unit
22 CCD (imaging means)
48 Timing generator (second signal generating means and resetting means)
66 Video encoder (first signal generating means)
80 Crystal oscillator (second oscillation means)
82 Ceramic oscillator (first oscillation means)

Claims (8)

Imaging means for imaging a subject;
First oscillating means for generating a first clock signal having a predetermined period which is a reference for the operation of the reproduction system ;
First signal generating means for generating, based on the first clock signal, a reproduction vertical synchronizing signal having a predetermined first period related to reproduction of image data obtained by imaging by the imaging means;
Second oscillating means for generating a second clock signal serving as a reference for the operation of the imaging system having a period different from that of the first clock signal;
An imaging vertical synchronization signal related to imaging by the imaging means having a period longer than a second period obtained by multiplying the first period by P (P is a natural number determined in advance according to an operation mode) is the second clock signal. And generating the imaging vertical synchronization signal by resetting the operation for generating the imaging vertical synchronization signal every second period with reference to the reproduction vertical synchronization signal. A second signal generating means for synchronizing the imaging vertical synchronizing signal with the reproducing vertical synchronizing signal in the second period ;
Digital camera equipped with. The digital camera according to claim 1, wherein the second signal generation unit generates the imaging vertical synchronization signal so as to have a period equal to or longer than a period obtained by adding a predetermined offset value to the second period. The offset value is determined based on an error according to an environmental change in each period in the first clock signal and the second clock signal, and each machine difference in the first oscillation unit and the second oscillation unit. The digital camera according to claim 2, wherein the period of the imaging vertical synchronization signal is determined to be longer than P times the first period based on at least one of the corresponding errors. The operation mode includes a focus control mode that is a mode for performing focus control, a through image mode that is a mode for reproducing a through image obtained by continuous imaging by the imaging unit, and a mode for performing exposure correction. Each of the exposure correction modes is provided, and the value of P corresponding to the focus control mode is smaller than the value of P corresponding to the through image mode and the exposure correction mode. 4. The digital camera according to any one of items 3. Imaging means for imaging a subject, first oscillation means for generating a first clock signal having a predetermined period as a reference for the operation of the reproduction system , and reference for operation of the imaging system having a period different from that of the first clock signal a digital camera control method having a second oscillating means for generating a second clock signal which becomes,
Based on the first clock signal, a vertical synchronization signal for reproduction of a predetermined first period related to reproduction of image data obtained by imaging by the imaging means is generated ,
An imaging vertical synchronization signal related to imaging by the imaging means having a period longer than a second period obtained by multiplying the first period by P (P is a natural number determined in advance according to an operation mode) is the second clock signal. Is configured to generate based on
Said generating a vertical synchronizing signal for the imaging by resetting the operation of generating the imaging vertical synchronizing signal by said second signal generating means for each of the second periods the reproduced vertical synchronizing signal as a reference imaging A method for controlling a digital camera , wherein the vertical synchronizing signal for use is synchronized with the reproducing vertical synchronizing signal in the second period . The digital camera control method according to claim 5, wherein the imaging vertical synchronization signal is generated so as to have a period equal to or greater than a period obtained by adding a predetermined offset value to the second period. The offset value is determined based on an error according to an environmental change in each period in the first clock signal and the second clock signal, and each machine difference in the first oscillation unit and the second oscillation unit. The digital camera control method according to claim 6, wherein the period of the imaging vertical synchronization signal is determined to be longer than P times the first period based on at least one of the corresponding errors. For the digital camera, as the operation mode, a focus control mode that is a mode for performing focus control, a through image mode that is a mode for reproducing a through image obtained by continuous imaging by the imaging means, and exposure correction Each mode of exposure correction mode that is a mode to perform
The digital camera according to any one of claims 5 to 7, wherein the value of P corresponding to the focus control mode is set to a value smaller than the value of P corresponding to the through image mode and the exposure correction mode. Control method.

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