JP3442426B2 - Photoelectric conversion device - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a photoelectric conversion device,
In particular, the present invention relates to a photoelectric conversion device for controlling accumulation of a sensor used for AF (autofocus) of a camera with a simple configuration.

[0002]

2. Description of the Related Art Conventionally, a so-called phase-difference detection method has been used as an auto-focusing method for a camera, in which the amount of defocusing is detected from the amount of deviation of two images obtained from light beams passing through different pupils of a taking lens. It has been known. A CCD or the like is used as a photoelectric conversion sensor used in this system.

At the time of focus detection in a camera, it is necessary to control the amount of light received by the sensor for changes of about 20 EV. Therefore, as disclosed in Japanese Patent Laid-Open No. 57-64711, a photodiode for monitoring the light amount is provided in the vicinity of the light receiving element array, and the monitor starts the accumulation at the same time when the sensor starts to accumulate, and the output thereof has a predetermined voltage. A technique has been developed in which the accumulation of light in the light-receiving element array is completed at the time of reaching, and at the same time the accumulated charges are transferred to the CCD shift register section and the signals are sequentially read from the output section.

[0004]

By the way, recently, as in the above publication, the technology tends to shift from a single line type to a distance measuring type using a plurality of lines. Also at this time, the monitoring photodiode may be provided in the vicinity of the sensor for each line and controlled as described above. However, if the above configuration is adopted, the size of the monitor is restricted in layout, and the number of analog outputs that must be signal-processed increases, so that the circuit scale increases. Further, the area of the sensor chip is increased, which often causes a design problem.

The present invention has been made in view of the above problems, and is intended for distance measurement in a plurality of lines.
An object of the present invention is to provide a photoelectric conversion device which is not restricted by the size of the monitor or the area of the sensor chip is increased and the circuit size is not increased.

[0006]

That is, according to the present invention, a photographing screen is divided into a plurality of areas, and non-accumulation type photometric means for generating an output according to the amount of incident light in each area, and the divided areas. And a plurality of systems of charge storage type photoelectric conversion means arranged in the vicinity and a plurality of systems of charge storage of the charge storage type photoelectric conversion means. The accumulation starting means that starts at the same time, and the non-accumulation type photometric instrument
Charge accumulation for a set time based on the output of the stage,
Of the above-mentioned multiple systems of charge storage type photoelectric conversion means, focus detection
It is installed near the charge storage type photoelectric conversion means of the output system.
For reading the stored signal of the stored charge storage type photoelectric conversion means.
Reading means and the first reading means
Depending on the photoelectric conversion output obtained from the accumulated signal
Charge of photoelectric conversion means of charge storage type of system for detecting focus
Accumulation time setting means for setting the accumulation time, and the above accumulation time
The charge is accumulated for the time set by the setting means, and the focus
The stored signal of the charge storage type photoelectric conversion means of the detection system is
And a second reading means for reading .

[0007]

In the photoelectric conversion device of the present invention, first, the exposure
Of the line that you want to detect the focus in advance from the photometric output
Find the accumulation time of other nearby lines. Then, the accumulation end time of the line for focus detection is calculated from the signal read after the accumulation is completed at the above time, and the accumulation is performed for this time.
The focus detection data is obtained by reading the signal .

[0008]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing a configuration of a camera to which a photoelectric conversion device is applied according to an embodiment of the present invention.

In FIG. 1, the light flux passing through the taking lens 1 is split into two directions by the main mirror 2. One of them is guided to the eyepiece through the finder, and the other is guided to the AF module 4 by the sub-mirror 3. A above
The light flux guided to the F module 4 is photoelectrically converted by the AF sensor 5 and further signal-processed by the signal processing unit 6. The drive control unit 7 drives the photographing lens 1 by a predetermined amount by the processed signal.

Of the above luminous flux, the luminous flux guided to the finder is further guided to a photometric sensor 9 which is a light receiving element by a condenser lens 8 provided in the finder section. From the photometric sensor 9, photometric data is output.

FIG. 2 is a view showing the shape of the light receiving portion of the photometric sensor 9. As shown in the figure, the photometric sensor 9
Is divided into 13 with respect to the shooting screen. Then, a photometric value according to the brightness of each place is output, and each output is controlled by the photometric signal control unit 10 of FIG.
Sent to. Here, the central division portion is arranged so as to be related to a distance measuring system described later.

FIG. 3 is a block diagram showing a detailed structure of the AF sensor 5. The AF sensor 5 is 5A, 5B,
It has four photoelectric conversion element arrays 5C and 5D, and the size of one pixel of each sensor is the same. Regarding the number of pixels of each sensor, 5A and 5B each have 100 effective pixels, and 5C and 5D each have 80 effective pixels, and basically one pair constitutes one detection system. The AF sensors 5A and 5B shown in the figure correspond to a wide field of view of the film equivalent surface 17, and the AF sensors 5C and 5D receive a light beam corresponding to a narrow field (FIG. 4).
(A)).

Further, the Fn of the light beam guided to the detection system is
o. As shown in FIG. 4B, the AF sensor 5A,
The 5B pair receives the outer light flux, and the AF sensor 5C, 5D pair receives the light that has passed through the inner light flux. That is, as described above, the pair of AF sensors 5A and 5B has a wide field of view and a high defocus detection capability, and the pair of AF sensors 5C and 5D has a narrow field of view and a high detection accuracy. Further, the divided area of the side light sensor and the two distance measuring fields of view are substantially equal to each other.

Returning to FIG. 3, the structure of the AF sensor 5 will be described. To start the accumulation operation of each line sensor, a reset signal is input to the line selected by the reset signal control unit 12. The signal accumulated for a predetermined time from the start of accumulation is
The signal generated from the read control unit 11 transfers the accumulated charge from the charge accumulation unit in the sensor to the CCD shift register. The read control unit 11 also selects a line for reading.

The lines are selected line by line, for example, when only one line is used or when the accumulation operation is performed independently. The charges transferred to the CCD section are
The outputs selected by the output control unit 13 are sequentially output in a predetermined output order. Then, thereafter, the signal output is amplified to a predetermined level through the amplifier 14 whose amplification factor is determined by the signal amplification control unit 15.

Control units 11 to 15 related to the above control
Communicates with a CPU (not shown) via the I / O control unit 16 to set each operation. Next, referring to the time chart of FIG. 5 and the flowchart of FIG. 6,
The operation of the embodiment will be described.

When the focus detection operation is started, the CPU first examines the photometric output in order to determine the preliminary read time of the accumulated signal of the line having a low priority, which is different from the focus detection (steps S1 and S2). At this time, as described above, the fields of view of the distance measuring system and the photometric system are looking at substantially the same position. Therefore, even if there is a large difference in the amount of incident light for each detection system, some correction can be performed at this point.

Assuming that the output characteristics between two line pairs provided in the vicinity are substantially equal, the time characteristic of the output showing the maximum value in the output signal is 1 as shown in FIG. 7 (a).
It can be represented as one representative value, and shows an output proportional to the incident light amount with the accumulation time.

When the preliminary read time is determined, the CPU
Outputs the accumulation start signals Φ _R and Φ _T to the sensor in synchronization with the CCD drive clocks Φ ₁ and Φ ₂ (step S
3). In the case of the embodiment, both two line pairs are simultaneously reset. Then, after the accumulation is started, at the time set above, C
The PU outputs transfer pulses Φ _Ta and Φ _Tb to the sensor in order to read the signal on the preliminary read line (steps S4 and S).
5, S6). A method of selecting each line at this time will be described later. The accumulation end time of the line for focus detection is determined from the signal thus read (step S7).

When the accumulation time set in this way is reached (step S8), the CPU outputs transfer pulses Φ _Tc and Φ _Td to the sensor (step S9). Then, the signal OS used for focus detection is output in a predetermined order. CPU is
The output signal sampled and held at the timing of Φ _SH is A / D converted to perform focus detection calculation (step S
10).

Now, a method of determining the preliminary read time will be described. The output relationship between the photometry sensor and the distance measurement sensor when looking at the surface of uniform illuminance is adjusted in advance by EEP.
It is stored in the ROM (not shown). The CPU estimates the preliminary read time by performing this weighting on the photometric output.

If the subject is relatively bright and the accumulation end time is expected to end before 40 mS, the preliminary read time is set to 1 / n times the expected accumulation end time. Here, about 2 to 8 is suitable for processing. Here, the accumulation time of the focus detection line is determined from the signal read at the set time. However, when the subject is extremely bright, the accumulation of the focus detection line is saturated while the signal of the preliminary read line is being read. Therefore, in this case, each line is reset based on the result of the preliminary reading and the accumulation operation is performed again. The read time requires at least 2 mS when the A / D conversion time is 20 μS, and when the brightness is saturated, the read operation is reset and the accumulation operation is performed again.

When the subject is relatively dark, preliminary reading is performed 5 mS after the start of accumulation. The brightness that can be judged in this time has a limit on the low luminance side. This judgment level can be amplified 8 times by controlling the amplification factor and 2 times by adding the sensor output, and can be amplified up to 16 times in total.
It is possible to judge up to a signal that reaches an appropriate level at 0 mS (FIG. 7 (b)).

If the brightness cannot be judged even under this condition, preliminary reading is performed 10 mS after the start of accumulation. At this time, it is possible to judge up to 160 mS by the above method. This time is set as a limiter of the accumulation time. Therefore, the accumulation time of the focus detection line is controlled based on the signal at the time of preliminary reading that is read in three stages of reading time according to the brightness.

Further, since the accumulation time can be estimated in the accumulation control, when the signal reading time is sufficient, the CPU can perform the processing utilizing the time. For example, it is possible to judge the state of other parts of the system during this time, obtain the two-image interval for the signal read by the preliminary reading, and reduce the detection calculation amount of the focus detection line. In addition, the data for preliminary reading is S
Although the condition is poor in terms of / N, it is possible to determine the contrast of the subject to some extent. Therefore, when it is determined that detection is not possible due to low contrast, the defocus determination can be performed in a short time prior to the main reading.

FIGS. 8 and 9 show the read control unit 11 of FIG.
6A and 6B are diagrams illustrating a control example of a reset control unit 12; CPU sends operation command line SET to the sensor
The operation is instructed by T and SETR. When the combination of the signals of these two lines is set, the operation as shown in FIG. 9 is started. That is, Φ _T occurs when SETT = “1”, and Φ _R occurs when SETR = “1”. The command shown in FIG. 8 selects which line is read at this time.

As shown in FIG. 3, the two lines SETT and SETR are input to the read controller 11 and the reset controller 12, respectively. On the other hand, the communication line “LINSEL” is input to both the read control unit 11 and the reset control unit 12. From this line,
As shown in, serial data is clocked by "CKS
It is sent to the sensors 5A to 5D in synchronization with the rise of EL ".

When a line is selected by the communication, a clock pulse is input to the selected line when the command line is input. Here, FIG. 8 "LINS
A, B, C, and D of EL ″ are the first CCD lines of the respective lines of the AF sensors 5A to 5D, which are A ₂ , B ₂ , C ₂ , and D _2.
Represents the control of the second CCD of each line of the AF sensors 5A to 5D, that is, the gate of the line for addition. Further, in the figure, "Q" is Q = 1, and the output section is simultaneously switched to the addition output. That is, the read selection is selected at the same time as the transfer line selection.

The amplification factor of the signal amplification control unit 15 in FIG. 3 is set to "1" for the communication line AGCSEL, and the read control unit 1
1 and the signal CKSE input to the reset control unit 12
By L and LINSEL, as 4-bit data ×
The amplification factors of 1, × 2, × 4, and × 8 can be set from the outside.

FIG. 10 is a diagram showing the output of the read control unit shown in FIG. FIG. 10A shows the output timing when a pair of lines is selected. The timing of synchronizing the accumulated charge transfer pulse Φ _T to the CCD is such that Φ ₁ is “1” and Φ ₂ is “0”. The output after transfer is always Φ ₁ before Φ ₂ . The output signal is A, B or C, D
Are sequentially output in the order of. Here, the line pair selection is
It is assumed that the method described above is used.

FIG. 10 (b) shows the read timing when two line pairs are selected together. As shown in the same figure, Φ _1A is driven with respect to Φ _2A in the above relationship, so that the output is also alternately output from the A column before the B column. The same applies to the relationship between Φ _1C and Φ _2C .

Here, Φ _1A and Φ _1C are both performed when the Φ _T occurs in the “1” state, but thereafter, as shown in FIG. 10, Φ _1A is always preceded by Φ _1C . The timing is controlled so that it is output. Although an embodiment of the control is not shown, it can be easily realized by the CPU and the simple gate circuit of the selection unit, and therefore the description thereof is omitted here.

[0033]

As described above, according to the present invention, the distance is measured in a plurality of lines, and the size of the monitor is restricted in the layout, the sensor chip area is increased, and the circuit scale is increased. Since it is possible to provide a photoelectric conversion device that does not have any, it is possible to efficiently perform signal processing,
The external processing circuit can also be downsized.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a camera to which a photoelectric conversion device is applied in an embodiment of the present invention.

2 is a diagram showing a shape of a light receiving portion of the photometric sensor 9 of FIG.

FIG. 3 is a block diagram showing a detailed configuration of an AF sensor 5 in FIG.

FIG. 4A is a diagram showing a field of view of AF sensors 5A, 5B and 5C, 5D with respect to a film equivalent surface 17; FIG.
FIG. 4 is a diagram showing the relationship between the AF sensors 5A, 5B and 5C, 5D and the luminous flux.

FIG. 5 is a time chart for explaining the operation of the embodiment of the present invention.

FIG. 6 is a flowchart illustrating the operation of the embodiment of the present invention.

FIG. 7A is a diagram showing a time characteristic of an output showing a maximum value in an output signal, and FIG. 7B is a diagram showing a relation between a storage time of a focus detection line and brightness.

8 is a read control unit 11 and a reset control unit 12 shown in FIG.
It is a figure explaining the example of control of.

9 is a read control unit 11 and a reset control unit 12 shown in FIG.
It is a figure explaining the example of control of.

10 is a diagram showing an output of the read control unit of FIG.

[Explanation of symbols]

1 ... Shooting lens, 2 ... Main mirror, 3 ... Sub mirror,
4 ... AF module, 5, 5A, 5B, 5C, 5D ... A
F sensor, 6 ... Signal processing unit, 7 ... Drive control unit, 8 ... Condensing lens, 9 ... Photometric sensor, 10 ... Photometric signal control unit, 11
... Read-out control section, 12 ... Reset signal control section, 13 ... Output control section, 14 ... Amplifier, 15 ... Signal amplification control section.

Claims (2)

(57) [Claims] 1. A non-accumulation type photometric means which divides a photographing screen into a plurality of areas and produces an output according to the amount of incident light in each area, and a predetermined area of the divided areas is substantially equal. The area has a distance measuring field of view and must be placed in the vicinity.
A plurality of systems of charge storage type photoelectric conversion means, a storage start means for simultaneously starting charge storage of a plurality of systems of the charge storage type photoelectric conversion means, and the output of the non-storage type photometric means after starting the charge storage.
Charge accumulation for a set time based on
Among the standard charge storage photoelectric conversion means, the system for focus detection
Charge storage type photoelectric conversion means provided in the vicinity of the charge storage type photoelectric conversion means.
First reading for reading the accumulated signal of the product type photoelectric conversion means
Means and the accumulated signal read by the first reading means
A system for performing the focus detection according to the obtained photoelectric conversion output.
The charge storage time of the charge storage type photoelectric conversion means
The storage time setting means and the charge storage for the time set by the storage time setting means are performed.
A charge storage type photoelectric conversion means of a system for detecting the focus
And a second read-out means for reading out the accumulated signal of the photoelectric conversion device. 2. The data is read by the first reading means.
Based on the photoelectric conversion output obtained from the accumulated signal, focus detection or
Or read the information about the contrast of the subject in the second reading above.
To obtain before reading the accumulated signal by the projecting means
The photoelectric conversion according to claim 1, wherein
apparatus.