JP3926897B2 - Strobe device - Google Patents

Description

なお、該ＬＵＴにかかるデータは、上記ＲＯＭ１６に記憶されている。
【００３３】
以下、このＬＵＴについて詳細に説明する。
本実施形態においては、表１に示す如くＬＵＴを用い本発光の発光量を決定する。このようなＬＵＴを参照してストロボの発光量を制御する理由は、上述したように、発光の強度と時間との関係は図３に示すように非線形な関係になっており、発光時間と発光量との関係を関数的に求めるのが難しいからである。
【００３４】
すなわち、ストロボを発光させるためのメインコンデンサに蓄積されている全電荷から予備発光後の上記メインコンデンサに残留している全電荷を放出したときの発光（以下、この発光をフル発光という）の発光量と所定の発光量との比である相対発光量と、上記所定の発光量を得るに必要な発光時間との関係を表わしたＬＵＴを予め記憶手段にファイルとして記憶し、予備発光に基づいて演算された適正露光を得るに必要な相対発光量に対応する発光時間を上記ＬＵＴより参照してストロボの発光時間を制御する。実際は、上記相対発光量は本発光時のフル発光における発光量を１００％とし、それを基準としたパーセント比で表されている。
【００３５】
従来は、上記ＬＵＴでいうならば相対発光量の配列を等差級数的に設定していたため相対発光量が大きくなる程、発光量の制御の精度が不必要に高くなり過ぎ、このため上記ＬＵＴを記憶するための記憶容量がたいへん大きくなるという問題点を有していた。一方、相対発光量が大きい部分の、相対発光量の配列の間隔を大きくすると、記憶容量は少なくなるが、相対発光量が小さい部分の発光量制御の精度が粗くなるという問題点があった。
【００３６】
本実施形態のストロボ装置はかかる事情を考慮してなされており、上記表１に示すＬＵＴにおける上記相対発光量を等比級数的に配列し、このＬＵＴを参照して発光時間を制御することで、本発光時の発光量を所望の精度で得るようにしたことを特徴とする。
【００３７】
ここで、相対発光量の求め方について説明する。
いま、適正露光に対応する画像データの平均値をＶＭとする。この値は被写体に拠らず一定である。また、任意の被写体に対して仮にフル発光の予備発光を行って得られた画像データの平均値をＶＦとすると、本発光時は予備発光時に対してＶＭ／ＶＦ倍の発光量が必要となる。
【００３８】
ところが実際には予備発光時の発光量は電力消費低減その他の目的のため、フル発光における発光量よりも少なく設定されている。したがって、任意の被写体に対して実際に照射される予備発光により得られた画像データの平均値ＶＰは、上記ＶＦより小さい値となる。
【００３９】
一方、上記表１に示したＬＵＴは、フル発光を基準にした相対発光量と発光時間との関係を示した表である。
【００４０】
したがって、上記実際に照射される予備発光により得られた画像データの平均値ＶＰをもって、直ちに上記ＬＵＴより本発光時の発光量を求めることはできない。
【００４１】
本実施形態では、以下の手順で実際の相対発光量を求め、さらに、上述したように該相対発光量に対応する発光時間で本発光を行う。
【００４２】
いま、フル発光の予備発光により得られた画像データの平均値をＶＦ、実際に照射される予備発光により得られた画像データの平均値をＶＰとすると、
Ｋ＝ＶＦ／ＶＰ ……（１）
の値Ｋ（Ｋ＞１）は、被写体に拠らず一定の値となるものであり、この値は予めＲＯＭ１６等に記憶させておくことができる。
【００４３】
したがって、上記任意の被写体に予備発光を行ったときに得られる画像データをフル発光に対する画像データに換算すると、
ＶＦ＝Ｋ・ＶＰ
となる。
【００４４】
結局、上記相対発光量Ｓは、
Ｓ＝ＶＭ／（Ｋ・ＶＰ） ……（２）
となる。
【００４５】
この（２）式で得られた相対発光量Ｓから、上記ＬＵＴを参照して発光時間を求め、該発光時間を制御することで所望の発光量を得る。
【００４６】
本第１の実施形態のストロボ装置によると、上記ＬＵＴにおける相対発光量を等比級数的に配列し、この表に基づき発光時間を制御することで、上記配列を等差級数的に配列した場合に比べ、少ない記憶容量で相対発光量の大きさによらず均一な高精度の制御が可能となる。
【００４７】
次に、本発明の第２の実施形態について説明する。
【００４８】
この第２の実施形態のストロボ装置は、その構成は基本的に上記第１の実施形態と同様であるが、逆光検出手段をさらに備えていることを特徴とする。その他の構成は上記第１の実施形態と同様であるので、ここでの詳しい説明は省略する。
【００４９】
ここで、上記逆光検出手段について説明する。
本第２の実施形態における測光手段は、ＣＣＤ３の全画面を６４の領域に分割し、各領域ごとにハード的に各画素データが平均化されたデータを撮像素子より求めている。そして、逆光検出は、図４に示すように６４分割された領域のうち中央部の４領域（斜線部で示す）の画像データの平均値と、当該領域以外の領域における画像データの平均値との比が所定以下の値のとき逆光と判断することで行う。
【００５０】
なお、撮影被写体が逆光状態のときは、上記中央部の４領域で測光を行うが、撮影被写体が逆光状態以外の通常の状態にあるときは、それよりも広い領域で測光する。本実施形態においては上記測光領域の大きさの切換はＣＰＵ８からの制御信号に基づき行われるが、このような切換は行わずに必要な測光領域の信号のみ処理し、実質的に測光領域の大きさを選択するようにしても良い。
【００５１】
ところで、従来、逆光下における撮影時には外光の影響を皆無にすることができないためアンダー露光になる場合があった。これにより、実際に撮影される画像は被写体が暗く写っていまうという不具合が生じていた。
【００５２】
すなわち、上記第１の実施形態の説明における（２）式において、任意の被写体に対して予備発光を行って得られた画像データの平均値ＶＰは、実際は予備発光に基づく光だけによる出力値ＶＰＡに自然光だけによる出力値ＶＰＢを加算したものである。すなわち、相対発光量Ｓは、
Ｓ＝ＶＭ／｛Ｋ（ＶＰＡ＋ＶＰＢ）｝ ……（３）
となる。
【００５３】
入射する外光が通常の場合であると、上記ＶＰＢの値はＶＰＡに対して十分小さく、相対発光量Ｓへの影響は無視できる。しかし、逆光時は、自然光が強く上記ＶＰＢの値が相対的に大きくなるため、実際に被写体に照射するに必要な相対発光量が本来必要とされる値より低い値になってしまう虞がある。
【００５４】
本第２の実施形態のストロボ装置はかかる事情を考慮し、逆光下における撮影時においても、被写体が暗く写ることなく適正露光で撮影を行い得ることを特徴とする。
【００５５】
すなわち、上記逆光検出手段により逆光と判断したとき、相対発光量Ｓ’は、
Ｓ’＝ＶＭ’／｛Ｋ（ＶＰＡ＋ＶＰＢ）｝ ……（４）
ただし、ＶＭ’＞ＶＭ
とし、逆光時には、通常時より本発光の発光量を大きくする。
【００５６】
このように、本第２の実施形態によると、逆光時に本発光時の発光量を変更し、逆光による検出誤差を補正し、適性露光での撮影を可能にするという効果を奏する。
【００５７】
なお、本第２の実施形態においては、上記第１の実施形態において採用した、相対発光量を等比級数的に配列したＬＵＴを用いることは必ずしも必須の要件ではなく、従来の等差級数的な配列に準じて記憶された相対発光量と発光時間との関係を表わすＬＵＴを用いても良い。
【００５８】
次に、本発明の第３の実施形態について説明する。
【００５９】
この第３の実施形態のストロボ装置は、その構成は基本的に上記第１の実施形態と同様であるが、予備発光時の露光時間を本発光時の露光時間よりも短く設定することを特徴とする。その他の構成は上記第１の実施形態と同様であるので、ここでの詳しい説明は省略する。
【００６０】
ところで、予備発光時においては、予備発光による反射光から得られる測光データのみを得るのが望ましいが、予備発光時の露光時間を本発光時の露光時間と等しくした場合を想定すると、図５に示すように、外光の影響が大きく測光誤差が大きくなる虞がある。
【００６１】
本第３の実施形態のストロボ装置は、かかる点を考慮してなされており、予備発光時の露光時間を本発光時の露光時間よりも短く設定することで、外光より予備発光の発光量を相対的に大きくし、検出精度を向上することを特徴とする。
【００６２】
図５は、本第３の実施形態のストロボ装置において、予備発光および本発光時における発光強度特性に対する予備発光時および本発光時の露光時間の関係を示した線図である。
【００６３】
図に示すように、本第３の実施形態のストロボ装置においては、本発光時の露光時間に対して予備発光時の露光時間を短く設定している。これにより、相対的に外光より予備発光の発光量が大きくなり、検出精度が向上する。
【００６４】
次に、本発明の第４の実施形態について説明する。
【００６５】
この第４の実施形態のストロボ装置は、その構成は基本的に上記第１の実施形態と同様であるが、上記第２の実施形態の如く逆光検出手段を有し、通常の外光が入光している場合と逆光が入光している場合とで予備発光の露光時間を変化させていることを特徴とする。その他の構成は上記第１の実施形態と同様であるので、ここでの詳しい説明は省略する。
【００６６】
図６は、本第４の実施形態のストロボ装置において、通常の予備発光時における露光時間と逆光時の予備発光時における露光時間との関係を示した線図である。
【００６７】
この実施形態のストロボ装置は、上記第２の実施形態と同様の逆光検出手段と有し、この逆光検出手段で逆光を検出した際には、図６示すように、予備発光時の露光時間を通常に対して短く設定する。
【００６８】
逆光時は通常時と比べて外光の光量が大きく（図６参照）、露光時間を長くすると予備発光時により外光の影響を受けやすくなり検出値精度が低下する。本実施形態はかかる事情を考慮し、逆光時には予備発光の露光時間をより短くすることで精度向上を図り、不適正な露光撮影防止に貢献する。
【００６９】
【発明の効果】
以上説明したように本発明によれば、高精度な本発光制御が可能となるストロボ装置を提供できる。
【図面の簡単な説明】
【図１】本発明の第１の実施形態であるストロボ装置の構成を示したブロック図である。
【図２】上記第１の実施形態のストロボ装置において、予備発光に基づく本発光の発光量演算動作および撮像動作を示したフローチャートである。
【図３】一般のストロボの発光強度と発光時間との関係を示した線図である。
【図４】本発明の第２の実施形態のストロボ装置における逆光検出手段を説明する図である。
【図５】本発明の第３の実施形態のストロボ装置において、予備発光および本発光時における発光強度特性に対する予備発光時および本発光時の露光時間の関係を示した線図である。
【図６】本発明の第４の実施形態のストロボ装置において、通常の予備発光時における露光時間と逆光時の予備発光時における露光時間との関係を示した線図である。
【符号の説明】
１…撮影レンズ
２…シャッタ
３…撮像素子（ＣＣＤ）
４…増幅回路
５…信号処理回路
６…Ａ／Ｄ回路
７…メモリ
８…ＣＰＵ
９…タイミングジェネレータ
１０…シャッタ制御回路
１１…発光量制御回路
１３…ストロボ発光管
１４…ストロボ発光モードスイッチ
１５…レリーズスイッチ
１６…ＲＯＭ[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a strobe device, and more particularly to a strobe device that emits auxiliary light toward a subject prior to shooting and performs preliminary light emission for setting the amount of main light emission.
[0002]
[Prior art]
Generally, when photographing is performed with an imaging device such as a camera, when the amount of light is insufficient with only natural light, the shortage is compensated by a strobe device, for example. In this strobe device, preliminary light emission is performed prior to the main light emission in order to optimize the main light emission amount at the time of shooting, and the light emission amount of the main light emission at the time of actual exposure is set. In this way, when controlling the light emission amount of the main light emission, for example, a control circuit including a dedicated light receiving element for controlling the light emission amount in a strobe device as disclosed in JP-A-3-126383 is provided. Provided.
[0003]
Japanese Examined Patent Publication No. 5-44654 discloses an electronic camera system that uses an image sensor and sets a light emission amount of main light emission based on an integrated output without providing a dedicated light receiving element or control circuit. Has been.
[0004]
On the other hand, when determining the light emission amount in the main light emission, a LUT (Look Up Table) representing the relationship between the light emission amount in the main light emission and the light emission time is stored in advance in the storage means as a file. Technical means for controlling the light emission time are known.
[0005]
Hereinafter, light emission time control means in the main light emission using this LUT will be briefly described.
[0006]
In general, since the relationship between the light emission intensity of the strobe and the light emission time is a non-linear relationship as shown in FIG. 3, it is difficult to obtain the relationship between the light emission time and the light emission amount as a function. For this reason, there has been proposed a technical means for obtaining a desired light emission amount by controlling the light emission time using a table in which the relationship between the light emission time and the light emission amount is experimentally obtained in advance.
[0007]
That is, the relationship between the predetermined light emission amount (relative light emission amount) and the light emission time is tabulated based on full light emission (100% light emission), and the relative light emission amount necessary for obtaining the appropriate exposure calculated based on the preliminary light emission is obtained. The flash emission time is controlled with reference to the corresponding emission time from the above table.
[0008]
[Problems to be solved by the invention]
However, in the conventional light emission time control means as described above, the arrangement of the relative light emission amounts is set in a differential series in a table in which the relationship between the light emission time and the light emission amount is experimentally obtained in advance.
[0009]
For this reason, as the relative light emission amount increases, the control accuracy of the light emission amount becomes unnecessarily high, and thus the storage capacity for storing the above table becomes very large.
[0010]
On the other hand, when the interval of the arrangement of the relative light emission amounts is increased in the portion where the relative light emission amount is large, the storage capacity is reduced, but there is also a problem that the accuracy of the light emission amount control in the portion where the relative light emission amount is small becomes rough.
[0011]
The present invention has been made in view of such problems, and an object of the present invention is to provide a strobe device capable of highly accurate main light emission control.
[0012]
[Means for Solving the Problems]
The first strobe device of the present invention includes a preliminary light emission means for performing preliminary light emission to irradiate a subject with auxiliary light prior to photographing and obtaining a light emission amount of the main light emission, and preliminary light emission by the preliminary light emission means. receiving an imaging device for photoelectrically converting light reflected by the subject was, the exposure time control means for controlling the exposure time of the imaging device, based on an output signal of the image sensor is photoelectrically converted in the preliminary light emission, the A relative light emission amount calculating means for calculating a relative light emission amount that is a ratio of a light emission amount to a predetermined reference light emission amount, a plurality of arrays of the relative light emission amounts that increase or decrease in relation to a geometric series, and A storage means for storing a file composed of a combination of a light emission time necessary for obtaining a light emission quantity in main light emission corresponding to each relative light emission quantity, and Anda main emission time control means for controlling the light emission time of the light emission time of the reading by the main light emission of the light emission corresponding to the relative light amount calculated by the light emission amount calculating means, said exposure time control means, The exposure time of the image sensor in the preliminary light emission is set shorter than the exposure time of the image sensor in the main light emission .
[0013]
The second strobe device according to the present invention includes a backlight detection unit for detecting whether or not the shooting subject is in a backlight state in the first strobe device, and the backlight detection unit causes the shooting subject to be in a backlight state. The exposure time control means sets the exposure time of the image sensor in the preliminary light emission to be shorter than that when the photographing subject is in a normal state other than the backlight state. To do.
[0014]
According to a third strobe device of the present invention, in the first strobe device, a backlight detection means for detecting whether or not a photographing subject is in a backlight state, and a subject that has received preliminary light emission by the preliminary light emission means. And a photometric area setting means for setting the size of a photometric area for photoelectric conversion in the imaging device, and when the backlight detection means determines that the photographic subject is in a backlight condition, The size of the photometry area in the preliminary light emission is set to be narrower than that in the case where the photographing subject is in a normal state other than the backlight state .
[0015]
According to a fourth strobe device of the present invention, the first strobe device includes a backlight detection unit for detecting whether or not the shooting subject is in a backlight state, and the backlight detection unit causes the shooting subject to be in a backlight state. when it is determined that it is, the present light emission time control unit, photographed subject the light emission amount of the light emission and to control so many than when in the normal state other than backlight state.
[0016]
According to a fifth strobe device of the present invention, the third strobe device includes a backlight detection unit for detecting whether or not the shooting subject is in a backlight state, and the backlight detection unit causes the shooting subject to be in a backlight state. Is determined, the size of the photometric area in the preliminary light emission is set narrower than that in the normal state other than the backlight state.
[0017]
A sixth strobe device according to the present invention includes a backlight detection unit for detecting whether or not a photographing subject is in a backlight state in the third strobe device, and the backlight detection unit causes the photographing subject to be in a backlight state. When it is determined that, the amount of light emission in the main light emission is controlled to be larger than that in the normal state other than the backlight state.
[0018]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings.
[0019]
FIG. 1 is a block diagram showing a configuration of a strobe device according to the first embodiment of the present invention.
[0020]
The strobe device of this embodiment includes a photographic lens 1 that receives a subject image, a shutter 2 that is disposed behind the photographic lens 1 and also serves as an aperture, and a subject image that enters the photographic lens 1 during photographing. A solid-state imaging device 3 such as a CCD that photoelectrically converts light reflected by a subject image that has undergone preliminary light emission by preliminary light emission means performed prior to imaging, and an image signal captured by the imaging device 3 Amplifying circuit 4 for amplifying, signal processing circuit 5 for sampling and holding the image signal amplified by this amplifying circuit 4, A / D circuit 6 for analog / digital conversion of the signal from this signal processing circuit 5, and A / Based on the memory 7 for storing the output signal from the D circuit 6 and the output signal from the A / D circuit 3 or the memory 7, the light emission amount of the strobe arc tube 13 is calculated. A central processing unit (CPU) 8 that controls the drive of each component of the strobe device, a timing generator (TG) 9 that generates a timing signal for driving the CCD 3, and the shutter 2 under the control of the CPU 8 For example, a strobe arc tube 13 made of an Xe tube, a light emission amount control circuit 11 for controlling the light emission amount of the strobe arc tube 13 under the control of the CPU 8, and the strobe arc tube 13 Trigger electrode 12, strobe light emission mode switch (SW 1) 14 connected to the CPU 8, release switch (shooting operation start switch SW 2) 15 connected to the CPU 8, and ROM 16 for storing predetermined values for light emission, etc. The main part consists of
[0021]
The size of the photometric area of the CCD 3 is switched based on a control signal from the CPU 8.
[0022]
The amplifier circuit 4 amplifies the output signal of the CCD 3 with a predetermined amplification factor based on a control signal from the CPU 8.
[0023]
Further, the signal processing circuit 5 performs predetermined signal processing such as gamma correction and color correction on the image signal amplified by the amplifier circuit 4.
[0024]
Further, when the strobe light emission mode switch 14 is turned on, the CPU 8 emits strobe light, and when the release switch 15 is turned on, the photographing operation is started under the control of the CPU 8.
[0025]
With reference to the flowchart shown in FIG. 2, a description will be given of the light emission amount calculation operation and the imaging operation of the main light emission based on the preliminary light emission in the strobe device according to the first embodiment having such a configuration.
[0026]
As shown in FIG. 2, when the release switch 15 is turned on (step S1), the CPU 8 sets an amplification factor m (step S2), and preliminary light emission is performed under the control of the CPU 8 at this amplification factor m (step S2). Step S3). Thereafter, A / D conversion is performed by the A / D circuit 6 (step S4), and the image data is stored in the memory 7 (step S5). In the present embodiment, the amplification factor m is set to 1.
[0027]
Next, an average value V1 of the image data by preliminary light emission is obtained under the control of the CPU 8 (step S6). Next, the CPU 8 calculates the light emission amount of the main light emission (step S7). This calculation method will be described in detail later.
[0028]
Thereafter, the CPU 8 controls the opening and closing of the shutter 2 and emits the main light from the strobe light emitting tube 13 (steps S8, S9, S10), and takes in the image data from the CCD 3 (step S11).
[0029]
The exposure time is controlled accurately using the electronic shutter of the CCD 3 as well.
[0030]
Further, in the photometry in only natural light and preliminary light emission, the entire screen may be divided into 64 regions, and data obtained by averaging each pixel data in hardware for each region may be obtained from the image sensor. Thereby, higher speed processing can be realized.
[0031]
Here, the light emission amount calculation method of the main light emission in step S7 will be described.
In the present embodiment, a method to be described later is basically based on an average value VM of image data corresponding to appropriate exposure and an average value VP of image data obtained by performing preliminary light emission on an arbitrary subject. The LUT (see Table 1) representing the relationship between the relative light emission amount and the light emission time is stored in advance as a file in the storage means, and the light emission time of the main light emission is obtained by referring to this. Determine the amount of light emitted.
[0032]
[Table 1]

The data relating to the LUT is stored in the ROM 16.
[0033]
Hereinafter, this LUT will be described in detail.
In this embodiment, as shown in Table 1, the light emission amount of the main light emission is determined using the LUT. As described above, the reason for controlling the light emission amount of the strobe with reference to such an LUT is that the relationship between the light emission intensity and time is non-linear as shown in FIG. This is because it is difficult to obtain the relationship with the quantity functionally.
[0034]
That is, light emission when the total charge remaining in the main capacitor after preliminary light emission is released from the total charge accumulated in the main capacitor for causing the strobe to emit light (hereinafter, this light emission is referred to as full light emission). The LUT representing the relationship between the relative light emission amount, which is the ratio of the amount of light emission and the predetermined light emission amount, and the light emission time required to obtain the predetermined light emission amount is stored in advance as a file in the storage means, and based on the preliminary light emission The light emission time corresponding to the relative light emission amount necessary for obtaining the proper exposure calculated is referred to from the LUT, and the light emission time of the strobe is controlled. Actually, the relative light emission amount is expressed as a percentage based on 100% of the light emission amount in full light emission during main light emission.
[0035]
Conventionally, in terms of the LUT, since the arrangement of relative light emission amounts is set in a differential series, the accuracy of light emission amount control becomes unnecessarily high as the relative light emission amount increases. There is a problem that the storage capacity for storing the memory becomes very large. On the other hand, if the interval of the arrangement of the relative light emission amounts is increased in the portion where the relative light emission amount is large, the storage capacity is reduced, but the accuracy of the light emission amount control in the portion where the relative light emission amount is small becomes rough.
[0036]
The strobe device according to the present embodiment is made in consideration of such circumstances. By arranging the relative light emission amounts in the LUT shown in Table 1 in a geometric series and controlling the light emission time with reference to the LUT. The light emission amount during the main light emission is obtained with desired accuracy.
[0037]
Here, how to obtain the relative light emission amount will be described.
Now, let VM be the average value of image data corresponding to proper exposure. This value is constant regardless of the subject. Further, assuming that the average value of image data obtained by performing preliminary light emission of a full light emission for an arbitrary subject is VF, a light emission amount that is VM / VF times that for preliminary light emission is required for main light emission. .
[0038]
However, the amount of light emitted during preliminary light emission is actually set to be smaller than the amount of light emitted during full light emission for other purposes. Therefore, the average value VP of the image data obtained by the preliminary light emission that is actually irradiated to an arbitrary subject is smaller than the above VF.
[0039]
On the other hand, the LUT shown in Table 1 is a table showing the relationship between the relative light emission amount and the light emission time on the basis of full light emission.
[0040]
Therefore, the light emission amount during the main light emission cannot be immediately obtained from the LUT by using the average value VP of the image data obtained by the preliminary light emission actually irradiated.
[0041]
In the present embodiment, the actual relative light emission amount is obtained by the following procedure, and further, as described above, the main light emission is performed in the light emission time corresponding to the relative light emission amount.
[0042]
Now, assuming that the average value of the image data obtained by the preliminary emission of full emission is VF, and the average value of the image data obtained by the preliminary emission actually irradiated is VP,
K = VF / VP (1)
The value K (K> 1) is a constant value regardless of the subject, and this value can be stored in advance in the ROM 16 or the like.
[0043]
Therefore, when converting the image data obtained when performing preliminary light emission to the arbitrary subject into image data for full light emission,
VF = K ・ VP
It becomes.
[0044]
After all, the relative light emission amount S is
S = VM / (K · VP) (2)
It becomes.
[0045]
From the relative light emission amount S obtained by the equation (2), a light emission time is obtained with reference to the LUT, and a desired light emission amount is obtained by controlling the light emission time.
[0046]
According to the strobe device of the first embodiment, the relative light emission amounts in the LUT are arranged in a geometric series, and the arrangement is arranged in a geometric series by controlling the light emission time based on this table. Compared to the above, uniform and highly accurate control is possible with a small storage capacity regardless of the relative light emission amount.
[0047]
Next, a second embodiment of the present invention will be described.
[0048]
The strobe device of the second embodiment is basically the same in configuration as the first embodiment, but is further provided with a backlight detection means. Since other configurations are the same as those of the first embodiment, detailed description thereof is omitted here.
[0049]
Here, the backlight detection means will be described.
The photometric means in the second embodiment divides the entire screen of the CCD 3 into 64 areas, and obtains data obtained by averaging the pixel data in terms of hardware for each area from the image sensor. Then, as shown in FIG. 4, the backlight detection includes the average value of the image data in the central four regions (indicated by the hatched portion) among the 64 divided regions and the average value of the image data in the regions other than the region. This is performed by determining that the light is backlit when the ratio of the above is a predetermined value or less.
[0050]
Note that when the photographic subject is in the backlight state, photometry is performed in the four areas at the center, but when the photographic subject is in a normal state other than the backlight state, the photometry is performed in a wider area. In the present embodiment, the size of the photometry area is switched based on a control signal from the CPU 8, but only the necessary photometry area signal is processed without performing such switching, and the size of the photometry area is substantially increased. You may make it select.
[0051]
Conventionally, there has been a case where underexposure occurs because the influence of external light cannot be completely eliminated during photographing under backlight. As a result, there has been a problem in that the subject actually appears dark in the actually captured image.
[0052]
That is, in the expression (2) in the description of the first embodiment, the average value VP of image data obtained by performing preliminary light emission on an arbitrary subject is actually an output value VPA based only on light based on preliminary light emission. And an output value VPB based only on natural light. That is, the relative light emission amount S is
S = VM / {K (VPA + VPB)} (3)
It becomes.
[0053]
If the incident external light is normal, the value of VPB is sufficiently small with respect to VPA, and the influence on the relative light emission amount S can be ignored. However, since the natural light is strong and the VPB value is relatively large during backlighting, the relative light emission amount that is actually required for irradiating the subject may be lower than the originally required value. .
[0054]
Considering such circumstances, the strobe device of the second embodiment is characterized in that even when shooting under backlight, the subject can be shot with appropriate exposure without being dark.
[0055]
That is, when the backlight detection unit determines that the backlight is backlit, the relative light emission amount S ′ is
S ′ = VM ′ / {K (VPA + VPB)} (4)
However, VM '> VM
In the case of backlighting, the light emission amount of the main light emission is increased from that in the normal time.
[0056]
As described above, according to the second embodiment, there is an effect that the amount of light emission during main light emission is changed during backlighting, detection errors due to backlighting are corrected, and photographing with appropriate exposure is enabled.
[0057]
In the second embodiment, it is not always essential to use the LUT in which the relative light emission amounts are arranged in a geometric series, which is adopted in the first embodiment. Alternatively, an LUT that represents the relationship between the relative light emission amount and the light emission time stored in accordance with various arrangements may be used.
[0058]
Next, a third embodiment of the present invention will be described.
[0059]
The strobe device of the third embodiment is basically the same in configuration as the first embodiment, but is characterized in that the exposure time during preliminary light emission is set shorter than the exposure time during main light emission. And Since other configurations are the same as those of the first embodiment, detailed description thereof is omitted here.
[0060]
By the way, in the preliminary light emission, it is desirable to obtain only the photometric data obtained from the reflected light by the preliminary light emission. However, assuming that the exposure time in the preliminary light emission is equal to the exposure time in the main light emission, FIG. As shown, the influence of external light is large and the photometric error may increase.
[0061]
The strobe device of the third embodiment is made in consideration of such points, and by setting the exposure time at the time of preliminary light emission shorter than the exposure time at the time of main light emission, the light emission amount of the preliminary light emission from the external light Is made relatively large to improve detection accuracy.
[0062]
FIG. 5 is a diagram showing the relationship of the exposure time during preliminary light emission and main light emission with respect to the emission intensity characteristics during preliminary light emission and main light emission in the strobe device of the third embodiment.
[0063]
As shown in the drawing, in the strobe device of the third embodiment, the exposure time during preliminary light emission is set shorter than the exposure time during main light emission. Thereby, the amount of preliminary light emission is relatively larger than that of external light, and the detection accuracy is improved.
[0064]
Next, a fourth embodiment of the present invention will be described.
[0065]
The strobe device of the fourth embodiment is basically the same in configuration as the first embodiment, but has a backlight detection means as in the second embodiment, and receives normal outside light. It is characterized in that the exposure time of the preliminary light emission is changed between the case where the light is illuminated and the case where the backlight is incident. Since other configurations are the same as those of the first embodiment, detailed description thereof is omitted here.
[0066]
FIG. 6 is a graph showing the relationship between the exposure time during normal preliminary light emission and the exposure time during preliminary light emission during backlighting in the strobe device of the fourth embodiment.
[0067]
The strobe device of this embodiment has the same backlight detection means as in the second embodiment, and when the backlight detection means detects the backlight, as shown in FIG. Set it shorter than normal.
[0068]
The amount of external light is larger in the backlight than in the normal state (see FIG. 6), and if the exposure time is lengthened, it is more easily affected by the external light during the preliminary light emission, and the detection value accuracy is lowered. In consideration of such circumstances, the present embodiment improves accuracy by shortening the exposure time for preliminary light emission during backlighting, thereby contributing to prevention of inappropriate exposure photography.
[0069]
【The invention's effect】
As described above, according to the present invention, it is possible to provide a strobe device that can perform the main light emission control with high accuracy.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of a strobe device according to a first embodiment of the present invention.
FIG. 2 is a flowchart showing a light emission amount calculation operation and an imaging operation of main light emission based on preliminary light emission in the strobe device of the first embodiment.
FIG. 3 is a diagram showing the relationship between the light emission intensity and the light emission time of a general strobe.
FIG. 4 is a diagram illustrating a backlight detection unit in a strobe device according to a second embodiment of this invention.
FIG. 5 is a diagram showing the relationship between the exposure time during preliminary light emission and main light emission with respect to the emission intensity characteristics during preliminary light emission and main light emission in the strobe device according to the third embodiment of the present invention.
FIG. 6 is a diagram showing the relationship between the exposure time during normal preliminary light emission and the exposure time during preliminary light emission during backlight in the strobe device of the fourth embodiment of the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Shooting lens 2 ... Shutter 3 ... Image sensor (CCD)
4 ... amplifier circuit 5 ... signal processing circuit 6 ... A / D circuit 7 ... memory 8 ... CPU
DESCRIPTION OF SYMBOLS 9 ... Timing generator 10 ... Shutter control circuit 11 ... Light emission amount control circuit 13 ... Strobe light emission tube 14 ... Strobe light emission mode switch 15 ... Release switch 16 ... ROM

Claims (4)

Preliminary light emission means for performing preliminary light emission to irradiate the subject with auxiliary light prior to shooting and to determine the amount of main light emission;
An image sensor that photoelectrically converts light reflected by a subject that has undergone preliminary light emission by the preliminary light emission means;
Exposure time control means for controlling the exposure time of the image sensor;
Relative light emission amount calculating means for calculating a relative light emission amount that is a ratio of a light emission amount in the main light emission to a predetermined reference light emission amount, based on an output signal of the image sensor photoelectrically converted in the preliminary light emission;
Stores a file consisting of a combination of an array of a plurality of relative light emission amounts that increase or decrease in relation to a geometric series and a light emission time necessary to obtain a light emission amount in main light emission corresponding to each of the plurality of relative light emission amounts. Storage means for
A main light emission time control means for reading the light emission time of the main light emission corresponding to the relative light emission amount calculated by the relative light emission amount calculation means from the storage means, and controlling the light emission time of the main light emission ;
Comprising
The strobe device, wherein the exposure time control means sets an exposure time of the image sensor in the preliminary light emission shorter than an exposure time of the image sensor in the main light emission . A backlight detection unit for detecting whether or not the photographing subject is in a backlight state; and when the backlight detection unit determines that the photographing subject is in a backlight state, the exposure time control unit includes the preliminary light emission 2. The strobe device according to claim 1, wherein an exposure time of the image pickup device is set to be shorter than that in a normal state other than a backlight state. Backlight detection means for detecting whether or not a photographing subject is in a backlight state, and a size of a photometric area in which light reflected by the subject that has received preliminary light emission by the preliminary light emission irradiation means is photoelectrically converted by the imaging device A photometric area setting means for setting the brightness, and when the backlight detection means determines that the photographic subject is in a backlit state, the size of the photometric area in the preliminary light emission The strobe device according to claim 1, wherein the strobe device is set narrower than that in a normal state . A backlight detection unit for detecting whether or not the shooting subject is in a backlight state; and when the backlight detection unit determines that the shooting subject is in a backlight state, the main light emission time control unit 2. The strobe device according to claim 1, wherein the amount of emitted light is controlled to be larger than that in a normal state other than a backlit state.

Images