JP3903493B2 - Automatic focus detection device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an automatic focus detection apparatus that performs focus detection calculation on a subject image obtained by an accumulated charge type light receiving element to detect a focus state, and particularly projects auxiliary light to the subject when the brightness of the subject is low. The present invention relates to an automatic focus detection apparatus that enables focus detection.
[0002]
[Prior art]
The dynamic range of the subject luminance is considerably wider than the dynamic range of the subject image (determined by the number of bits of the A / D converter) obtained by a storage charge type light receiving element such as a CCD. On the other hand, the signal processing level after the focus detection calculation is desired to be substantially constant.
[0003]
Therefore, when the focus detection calculation is performed on the subject image obtained by the storage charge type light receiving element to detect the focus state, the accumulation of the storage charge type light receiving element is performed so that the signal level used in the focus detection calculation is substantially constant. Time is adjusted one by one in accordance with subject brightness or contrast.
The method for controlling the storage time of the storage charge type light receiving element is roughly divided into the first method for controlling the storage time in real time according to the storage amount at each storage time, and the next time from the current storage time and signal level. There is a second method for controlling the accumulation time.
[0004]
In the first method, since the accumulation time is controlled in real time, it is possible to respond to a sudden change in subject luminance during accumulation, but on the other hand, the luminance change is monitored independently in all the light receiving element pixels. Therefore, it is often the case that the accumulation time is controlled so that the average signal level of a plurality of pixels becomes a desired level.
On the other hand, in the second method, if subject brightness or contrast changes suddenly during storage, it is difficult to respond to it, but since it is software processing, all the light receiving element pixels are captured, for example, 1 There is an advantage that fine control is possible so that the peak level of the pixel becomes a predetermined level.
[0005]
Some automatic focus detection apparatuses of this type employ a method that enables focus detection by projecting auxiliary light onto a subject when the subject brightness or contrast is low.
[0006]
[Problems to be solved by the invention]
The automatic focus detection apparatus targeted by the present invention controls the accumulation time by the second method, but as described above, the second method responds to a sudden change in subject brightness during accumulation. Is difficult. Therefore, in an automatic focus detection apparatus that employs a method that enables focus detection by projecting auxiliary light onto a subject when the subject brightness or contrast is low, the accumulation time is controlled without auxiliary light. In this case, when the auxiliary light is projected, the following problem occurs.
[0007]
That is, when the accumulation time is controlled without auxiliary light, the accumulation time is naturally calculated in a dark state or in a low contrast state. When the auxiliary light is projected in this state, the signal level suddenly increases and sometimes reaches a saturation level exceeding the range of the A / D converter.
In such a case, conventionally, for example, the accumulation time is uniformly set to ¼ hour and the accumulation is performed again, so that it is appropriate until an appropriate signal level is obtained in a state where auxiliary light is projected. The accumulation operation is repeated a number of times, and it may take a long time for focus detection when auxiliary light is used.
[0008]
The present invention was created to solve such problems, and an object of the present invention is to provide an automatic focus detection apparatus having means that does not require re-accumulation control when auxiliary light is projected. It is in.
[0009]
[Means for Solving the Problems]
The configuration will be described with reference to FIG. 1 showing an embodiment of the present invention.
[0010]
The automatic focus detection apparatus according to claim 1,
The charge storage type light receiving element (1) that receives a subject image and outputs an output signal based on the light reception result, and the output signal and output signal at the time of the current light reception of the charge storage type light receiving element (1) Accumulation time calculation means (3, 4, 5) for calculating the accumulation time at the next light reception from the accumulation time, and accumulation operation control means for controlling the accumulation operation of the charge accumulation type light receiving element (1) according to the calculated accumulation time ( 6) and an auxiliary focus light emitting device (11, 13) for emitting the auxiliary light source (14) when the luminance or contrast of the subject is below a predetermined level , When the auxiliary light source is projected when the accumulation operation is controlled with the accumulation time calculated without light emission, the control means (7, 8, 9, 10, 11, 12 Characterized in that it comprises a.
[0011]
The automatic focus detection apparatus according to claim 2 receives the subject image and outputs the output signal based on the light reception result, and the current light reception of the charge storage type light receiving element (1). Storage time calculating means (3, 4, 5) for calculating the storage time at the next light reception from the output signal at the time and the storage time calculated based on the output signal, and the charge storage type light receiving element (1) according to the calculated storage time ) Storage operation control means (6) for controlling the storage operation, and auxiliary light emitting means (11, 13) for causing the auxiliary light source (14) to emit light when the luminance or contrast of the subject is below a predetermined level. In the automatic focus detection apparatus, the accumulation time correction means (7) for correcting the accumulation time, and the accumulation time correction means (7) are arranged between the accumulation time calculation means (3, 4, 5) and the accumulation operation control means (6). Turn off whether or not And switching means (8,9,10,11,12) provided replaced, switching means (8,9,10,11,12), the auxiliary light source (14) storage time calculation means without the emission of (3 4, 5), when the auxiliary light source (14) is projected after calculating the storage time , the storage time calculated without the light emission of the auxiliary light source calculated by the storage time calculation means (3, 4, 5) is stored. The accumulation time given to the correction means (7) and output by the accumulation time correction means (7) is output to the accumulation operation control means (6). When the auxiliary light source (14) is not projected, the accumulation time calculation means (3, 4) is output. 5) is output to the storage operation control means (6) as it is.
[0012]
(Function)
In the automatic focus detection apparatus according to claim 1, when the control unit starts projecting auxiliary light to the subject, the control unit corrects the accumulated time calculated so far to a shorter time, and uses the corrected accumulated time as a reference. The accumulation operation after the light emission is performed.
[0013]
As a result, the signal level used for focus detection does not increase transiently even if the subject brightness or contrast increases due to the auxiliary light projection, so the auxiliary light is used even if the auxiliary light projection is started. The focus state can be detected quickly as in the case of not doing so.
Specifically, the control means can be simply configured by the accumulation time correction means and the switching means as in the automatic focus detection apparatus according to claim 2.
[0014]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a block diagram showing the configuration of an automatic focus detection apparatus according to an embodiment of the present invention. 1, this automatic focus detection apparatus includes a charge storage type light receiving element (hereinafter referred to as “CCD”) 1, a focus detection circuit 2, an output level detection circuit 3, a next storage time calculation circuit 4, a current storage time holding circuit 5, Storage time control circuit 6, storage time correction circuit 7, selection switching circuit 8, 1-input 2-output switch 9, 2-input 1-output switch 10, control circuit 11, light emission / non-light emission recognition circuit 12, auxiliary light emission drive circuit 13 and a light emitting diode 14 and the like.
[0015]
The CCD 1 receives the subject image within a predetermined time under the control of the accumulation time control circuit 6, and outputs the received subject image signal to the focus detection circuit 2 and the output level detection circuit 3. The focus detection circuit 2 calculates the focus state of the subject from the output signal of the CCD 1. The output level detection circuit 3 detects the level of the output signal when the CCD 1 is currently receiving light, and outputs the detection result to the next accumulation time calculation circuit 4.
[0016]
The next accumulation time calculation circuit 4 calculates the accumulation time at the next light reception from the output signal level at the current light reception of the CCD 1 inputted from the output level detection circuit 3 and the accumulation time inputted from the current accumulation time holding circuit 5. The calculated accumulation time at the next light reception is output to the switching input terminal of the switch 9.
[0017]
One switching output terminal of the switch 9 is connected to one switching input terminal of the switch 10, and the other switching output terminal of the switch 9 is connected to the input terminal of the accumulation time correction circuit 7. The accumulation time correction circuit 7 replaces the accumulation time input from the other switching output terminal of the switch 9 with a shorter accumulation time and outputs it from one output terminal to the other switching input terminal of the switch 10 and also outputs the other output. A reset signal is output from the terminal to the reset terminal R of the selection switching circuit 8.
[0018]
The switch output terminal of the switch 10 is connected to the input terminal of the current storage time holding circuit 5 and the input terminal of the storage time control circuit 6. The current accumulation time holding circuit 5 holds the accumulation time input from the switching output terminal of the switch 10 as the current accumulation time. The accumulation time control circuit 6 controls the accumulation operation of the CCD 1 based on the accumulation time input from the switching output terminal of the switch 10.
[0019]
In the selection switching circuit 8, the set end S is connected to the output end of the light emission / non-light emission recognition circuit 12, and the output end Q is connected to the switching control input end of the two switches 9 and 10. That is, when the set signal is input from the light emission / non-light emission recognition circuit 12, the selection switching circuit 8 sets the level of the output terminal Q to a high level (hereinafter referred to as “H level”), and the reset signal is output from the accumulation time correction circuit 7. When input, the level of the output terminal Q is set to a low level (hereinafter referred to as “L level”). In the initial state such as when the power is turned on, the selection switching circuit 8 sets the level of the output terminal Q to the L level.
[0020]
The two switches 9 and 10 respectively select one switching output terminal and one switching input terminal when the output of the selection switching circuit 8 is at the L level, and respectively select the other when the output of the selection switching circuit 8 is at the H level. The switching output terminal and the other switching input terminal are selected.
The control circuit 11 is given luminance information or contrast information from the outside. This luminance information is a luminance value calculated from the output signal of a photometric sensor (not shown) or the accumulated amount of the CCD 1. The contrast information is calculated based on the output value from the CCD 1.
[0021]
The control circuit 11 determines whether or not the luminance of the subject is equal to or higher than a predetermined value based on the luminance information or contrast information of the external input. If the luminance is equal to or higher than the predetermined value, the output level is set to H level, for example. If so, the output level is set to L level.
The output terminal of the control circuit 11 is connected to the input terminal of the light emission / non-light emission recognition circuit 12 and the input terminal of the auxiliary light emission driving circuit 13.
[0022]
The light emission / non-light emission recognition circuit 12 recognizes that light emission has started when the output level of the control circuit 11 changes from the H level to the L level, and outputs a set signal. Thereby, the selection switching circuit 8 sets the level of the output terminal Q to the H level. Then, the selection switching circuit 8 sets the level of the output terminal Q to L level by the reset signal from the accumulation time correction circuit 7.
[0023]
A light emitting diode 14 that projects auxiliary light is connected to an output terminal of the auxiliary light emission driving circuit 13. When the output level of the control circuit 11 becomes L level, the auxiliary light emission drive circuit 13 drives the light emitting diode 10 to light.
The operation of the automatic focus detection apparatus according to the embodiment of the present invention will be described below with reference to FIGS. FIG. 2 is an operation flowchart of the automatic focus detection apparatus according to the first embodiment of the present invention. FIG. 3 is an operation flowchart of the automatic focus detection apparatus according to the second embodiment of the present invention.
[0024]
First, the operation of the first embodiment of the present invention will be described with reference to FIG. The first embodiment shows a control operation when the luminance of the subject is low. In FIG. 2, in S1, an initial setting process immediately after power-on is performed. That is, immediately after the power is turned on, there is no data stored in the CCD 1 and the current storage time is unknown. Therefore, the initial storage time is set in the current storage time holding circuit 5 and the output of the photometric sensor is output to the output level detection circuit 3, for example. For example, a predetermined value based on the above is set.
[0025]
As a result, the storage time initially set in the current storage time holding circuit 5 and the predetermined value set in the output level detection circuit 3 are both given to the next storage time calculation circuit 4, and the calculation operation of the next storage time is started.
Further, immediately after the power is turned on, the control circuit 11 holds the output at the H level, and the selection switching circuit 8 sets the level of the output terminal Q to the L level. 10 selects one of the switching input terminals.
[0026]
Therefore, the output of the next storage time calculation circuit 4 is directly given to the current storage time holding circuit 5 and the storage time control circuit 6 via the two switches 9 and 10.
In S2, the accumulation time control circuit 6 controls the operation of the CCD 1 to execute the accumulation operation. Immediately after the initial setting, the accumulation time control circuit 6 controls the accumulation operation of the CCD 1 according to the accumulation time calculated based on the initial value set in S1, and thereafter, the CCD 1 according to the accumulation time calculated based on the actual measurement value. Controls the accumulation operation.
[0027]
In S 3, the output level detection circuit 3 reads out the CCD 1, extracts the peak value, detects the maximum value, and gives the detection result to one input of the next accumulation time calculation circuit 4. The other input of the next storage time calculation circuit 4 is the output of the current storage time holding circuit 5.
In S4, the focus detection circuit 2 reads the CCD 1 and performs focus detection calculation.
[0028]
In S5, the next storage time calculation circuit 4 calculates the next storage time Tnext from the output of the output level detection circuit 3 and the output of the current storage time holding circuit 5, for example, according to the equation (1). Here, in Expression (1), the “target signal level” and the “actual signal level” are defined by the output value of the A / D converter.
Tnext = (current accumulation time (ms) × target signal level) / actual signal level (1) For example, in a specific numerical example, the current accumulation time (ms) is, for example, 100 ms, and the target signal level is 10 The next accumulation time Tnext is calculated assuming that the output value of the bit A / D converter is 512 and the actual signal level is the same as the output value of the 10-bit A / D converter is 400. In addition, since the calculation performed at the time of initial setting of S1 is based on an initial value, it cannot be overemphasized that calculation precision is low.
[0029]
Next, in S6, it is determined whether or not the focus detection circuit 2 has detected an in-focus state. If it is in the in-focus state, the determination in S6 is affirmative (YES) and this procedure is terminated. If it is not in the in-focus state, the determination in S6 is negative (NO), and the process proceeds to S7.
In S7, it is determined whether or not the image is dark, that is, whether or not the brightness of the subject is low enough to require auxiliary light projection and the focus detection circuit 2 is not in a state where the focus detection cannot be performed correctly. .
[0030]
If the determination in S7 is negative (NO), the luminance of the subject is bright enough to correctly detect the focus, so the control circuit 11 keeps the output level at the H level and maintains the switches 9 and 10 in the initial setting state. Then, the process proceeds to S11, the lens driving circuit is activated, the process returns to S2, and the routine of S2, S3, S4, S5, S6, S7, S11, and S2 is repeatedly executed until focus detection is performed in S6.
[0031]
During this time, the next storage time calculated by the next storage time calculation circuit 4 as described above is given to the current storage time holding circuit 5 and the storage time control circuit 6 via the switches 9 and 10, and the current storage operation of the CCD 1 is performed. While the time is controlled, the time for the next accumulation operation of the CCD 1 is repeatedly obtained, and the output level of the CCD 1 is controlled to a desired level. In the numerical example, the output level of the CCD 1 is controlled to be 512, and focus detection is performed.
[0032]
Of course, if the shooting scene is changed, the storage time calculated as the next storage time is based solely on the signal level and storage time before the change, and may deviate from the appropriate level. Then, there is no problem in the followability.
Next, as described above, the accumulation time of the CCD 1 is controlled by repeatedly executing the routine of S2, S3, S4, S5, S6, S7, S11, and S2, and even if an appropriate output value is obtained, the luminance of the subject is increased. If it falls, accumulation time will become long.
[0033]
Therefore, when the control circuit 11 detects that the subject brightness has fallen below the predetermined value in the process of repeatedly executing the routine of S2, S3, S4, S5, S6, S7, S11, and S2, the determination in S7 is affirmative. (YES), the process proceeds to S8, where it is determined whether or not the auxiliary light has already been emitted.
Since the auxiliary light has not been emitted this time, the determination in S8 is negative (NO), the auxiliary light is emitted in S9, the accumulation time is corrected in S10, and the process proceeds to S11.
[0034]
Specifically, when the control circuit 11 detects that the subject brightness has become equal to or lower than a predetermined value, the control circuit 11 sets the output level to L level, causes the auxiliary light emission drive circuit 13 to light the light emitting diode 14, and supplies auxiliary light to the subject. Irradiate.
At the same time, when the control circuit 11 changes the output level to the L level, the light emission / non-light emission recognition circuit 12 detects that the output level of the control circuit 11 has changed from the H level to the L level, and sends it to the selection switching circuit 8. A set signal is output.
[0035]
Then, since the selection switching circuit 8 sets the level of the output terminal Q to the H level, the two switches 9 and 10 perform the selection switching operation, and the switch 9 sends the output of the next storage time calculation circuit 4 to the storage time correction circuit 7. The switch 10 selects the output of the accumulation time correction circuit 7.
The accumulation time correction circuit 7 replaces the accumulation time input from the switch 9 with an accumulation time shorter than that and outputs it, and at the same time, gives a reset signal to the selection switching circuit 8. As a result, the storage time corrected to a short time is given to the storage time control circuit 6 and also to the current storage time holding circuit 5. Further, the selection switching circuit 8 is reset, the level of the output terminal Q is set to the L level, and the two switches 9 and 10 can perform the selection switching operation.
[0036]
As a result, the CCD 1 starts operating with the corrected accumulation time, the level of the output signal is given to the next accumulation time calculation circuit 4 as the current signal level, and the corrected accumulation time is set as the current accumulation time next time. The accumulation time calculation circuit 4 is given to calculate the next accumulation time.
[0037]
When the next accumulation time calculation circuit 4 calculates and outputs the next accumulation time based on the accumulated time and the signal level, the selection switching circuit 8 is reset, and the two switches 9 and 10 switch the accumulation time correction circuit 7. The selection switching operation to bypass is performed, and they are directly connected to each other.
Accordingly, when the auxiliary light emission has been completed and the determination is affirmative (YES) in S8 that has been made a round of S8 → S9 → S10 → S11 → S2 → S3 → S4 → S5 → S6 → S7 → S8 The process proceeds to S11, and the focus detection operation described above is performed by repeatedly executing the routine of S8 → S11 → S2 → S3 → S4 → S5 → S6 → S7 → S8 → S11. The next time calculated by the next accumulation time calculation circuit 4 Since the accumulation time is directly given to the current accumulation time holding circuit 5 and the accumulation time control circuit 6, even if auxiliary light is projected onto the subject and the luminance of the subject rapidly increases, the accumulation time of the CCD 1 is increased. A short accumulation time corresponding to the luminance is set in advance, and the operation can be performed based on the accumulation time.
[0038]
In short, under subject brightness that does not require auxiliary light projection, focus detection is performed by repeatedly executing the routine of S2, S3, S4, S5, S6, S7, S11, and S2. In S7, it is always determined whether or not it is necessary to project auxiliary light.
In S7, if it is determined that the luminance of the subject is reduced and auxiliary light projection is required, first, a routine of S7 → S8 → S9 → S10 → S11 → S2 → S3 → S4 → S5 → S6 → S7 is performed. Then, the auxiliary light is projected to correct the accumulation time, the next accumulation time is obtained with the corrected accumulation time, and the process proceeds directly from S8 to S11. Thereafter, S8 → S11 → S2 → S3 → S4 → S5 → S6 → The routine shifts to S7 → S8 → S11, and the focus detection based on the corrected accumulation time is performed.
Next, the operation of the second embodiment of the present invention will be described with reference to FIG. The second embodiment shows a control operation when the contrast of the subject is low.
[0039]
In FIG. 3, S31 to S36 correspond to S1 to S6 in FIG. 2, and the same operation is performed.
In the next S37, it is determined whether or not the contrast is low. If the determination in S37 is negative (NO), focus detection can be performed, but since the in-focus state has not been achieved, the output level is maintained at the control circuit 11 and the switches 9 and 10 are maintained in the initial setting state. Then, the process proceeds to S41, the lens driving circuit is activated, the process returns to S32, and the routine of S32 → S33 → S34 → S35 → S36 → S37 → S41 → S32 is repeatedly executed until focus detection is performed in S36.
[0040]
During this time, the next accumulation time calculation circuit 4 performs the same operation as in the first embodiment described above.
Next, if the determination in S37 is affirmative (YES), that is, if the contrast is low, the process proceeds to S38, and it is determined whether or not auxiliary light has already been emitted.
If the auxiliary light has not been emitted, the determination in S38 is negative (NO), the auxiliary light is emitted in S39, the accumulation time is corrected in S40, the process proceeds to S41, and the lens is based on the correction result. Carry out driving.
[0041]
The operations of the control circuit 11, the switches 9, 10, the storage time correction circuit 7, the selection switching circuit 8, the storage time holding circuit 5, and the next storage time calculation circuit 4 at this time are the same as those in the first embodiment described above. .
Next, in S38 in which the operations of S38, S39, S40, S41, S32, S33, S34, S35, S36, S37, and S38 are executed, it is determined that the auxiliary light has been emitted, and if the determination is affirmative (YES), this time. Proceed directly to S41.
[0042]
The focus detection operation described above is performed by repeatedly executing the routine of S38, S41, S32, S33, S34, S35, S36, S37, S38, and S41. The next accumulation time calculated by the next accumulation time calculation circuit 4 is performed. Is directly supplied to the current storage time holding circuit 5 and the storage time control circuit 6, so that even if the subject's contrast is suddenly increased by projecting auxiliary light on the subject, the storage time of the CCD 1 is increased to the increased subject contrast. It is preset to an appropriate short accumulation time. Therefore, the CCD 1 can operate with a short accumulation time set in this way.
[0043]
In short, under the subject contrast that does not require the projection of auxiliary light, the focus detection operation is performed by repeatedly executing the routine of S32 → S33 → S34 → S35 → S36 → S37 → S41 → S32. In S37 in the operation process, the control circuit 11 always determines whether “auxiliary light projection is necessary”.
If it is determined in S37 that the contrast of the subject is reduced and auxiliary light projection is required, first, the routine of S37 → S38 → S39 → S40 → S41 → S32 → S33 → S34 → S35 → S36 → S37 is performed. Execute. As in the first embodiment, auxiliary light is issued in S39, and the accumulation time is corrected in S40.
[0044]
From the above, in the next routine, the process proceeds from S38 to S41, and thereafter, the routine of S38->S41->S32->S33->S34->S35->S36->S37->S38-> S41 is repeated, and the same as in the first embodiment. In addition, focus detection based on the corrected accumulation time is performed.
This corrects the accumulation time so that the output level of the CCD 1 does not exceed the saturation level of the A / D converter under the projection of the auxiliary light, and the output level of the CCD 1 becomes an appropriate value. The number of repetitions can be significantly reduced, and the focus state can be detected quickly.
[0045]
The accumulation time to be corrected may be, for example, 1/2 hour with respect to the accumulation time immediately before the auxiliary light projection, or may be a non-linearly shorter time.
[0046]
【The invention's effect】
As described above, the automatic focus detection apparatus according to claim 1 corrects the accumulated time calculated so far to a shorter time and starts the corrected accumulated time when starting the projection of the auxiliary light onto the subject. Since the control means for performing the accumulation operation after the projection is provided as a reference, the signal level used for focus detection can be prevented from transiently increasing even if the subject brightness or the contrast is improved by the projection of the auxiliary light. Even when the auxiliary light projection is started, the focus state can be detected quickly as in the case where the auxiliary light is not used.
[0047]
Specifically, the control means can be simply configured by the accumulation time correction means and the switching means as in the automatic focus detection apparatus according to claim 2.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of an automatic focus detection apparatus according to an embodiment of the present invention.
FIG. 2 is a flowchart of the automatic focus detection apparatus according to the first embodiment of the present invention.
FIG. 3 is a flowchart of an automatic focus detection apparatus according to a second embodiment of the present invention.
[Explanation of symbols]
1 Charge storage type photo detector (CCD)
2 focus detection circuit 3 output level detection circuit 4 next accumulation time calculation circuit 5 current accumulation time holding circuit 6 accumulation time control circuit 7 accumulation time correction circuit 8 selection switching circuit 9, 10 switch 11 control circuit 12 light emission / non-light emission recognition circuit 13 Auxiliary light emission drive circuit 14 Light emitting diode

Claims (2)

A charge storage type light receiving element that receives a subject image and outputs an output signal based on the light reception result;
An accumulation time calculating means for calculating an accumulation time at the next light reception from an output signal at the time of light reception of the charge storage type light receiving element and an accumulation time calculated based on the output signal;
A storage operation control means for controlling a storage operation of the charge storage type light receiving element according to the calculated storage time;
In an automatic focus detection device comprising: an auxiliary light emitting means for emitting an auxiliary light source when the luminance or contrast of a subject is below a predetermined level;
Control means for controlling the accumulation operation in a time shorter than the accumulation time when projecting the auxiliary light source when the accumulation operation is to be controlled with the accumulation time calculated without light emission of the auxiliary light source. Automatic focus detection device. A charge storage type light receiving element that receives a subject image and outputs an output signal based on the light reception result;
An accumulation time calculating means for calculating an accumulation time at the next light reception from an output signal at the time of light reception of the charge storage type light receiving element and an accumulation time calculated based on the output signal;
A storage operation control means for controlling a storage operation of the charge storage type light receiving element according to the calculated storage time;
In an automatic focus detection device comprising: an auxiliary light emitting means for emitting an auxiliary light source when the luminance or contrast of a subject is below a predetermined level;
Storage time correction means for correcting the storage time;
Switching means for switching whether or not to put the storage time correction means between the storage time calculation means and the storage operation control means,
Said switching means, said when the accumulation time calculation means without emitting the auxiliary light source for projecting the auxiliary light source after calculating the accumulation time, no light emission of the auxiliary light source in which the accumulation time calculation means has calculated Is applied to the storage time correction means, the storage time corrected by the storage time correction means is output to the storage operation control means, and the output of the storage time calculation means is output when the auxiliary light source is not projected. An automatic focus detection apparatus characterized in that it is directly output to the accumulation operation control means.

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