JP7475872B2 - Lens device and imaging device having the same - Google Patents

Description

The present invention relates to a lens device equipped with an aperture means and an imaging device having the same.

Patent Document 1 discloses an imaging device having an aperture means (aperture blades, aperture unit) that is driven in the open or closed direction by an aperture drive unit having an actuator. The imaging device disclosed in Patent Document 1 measures the effective aperture value for each step and calculates the drive amount of the aperture blades at a predetermined effective aperture value.

Japanese Patent No. 6053429

However, when the aperture means is driven by microstep drive, the drive accuracy of the aperture means varies depending on the drive speed. That is, when the actuator (stepping motor) that drives the aperture means is accelerated or decelerated by microstep drive, the stepping motor (mechanical) operates while repeatedly delaying and advancing the drive command value (electrical) depending on the drive speed. As a result, when the aperture means is driven by acceleration or deceleration drive, the drive accuracy of the aperture means varies depending on the drive amount.

However, Patent Document 1 does not take into consideration variations in drive accuracy during acceleration or deceleration drive in microstep drive. For this reason, it is difficult for the imaging device disclosed in Patent Document 1 to control the aperture means at high speed and with high accuracy.

The present invention aims to provide a lens device and an imaging device that can control the aperture means at high speed and with high precision using microstep drive.

A lens device as one aspect of the present invention has an aperture means, a drive means for driving the aperture means, a memory means for storing a drive command value for driving the aperture means, and a control means for controlling the drive means based on the drive command value, wherein the drive command value is a drive command value set corresponding to a drive command amount which is a difference between a drive command value corresponding to a current aperture value of the aperture means and a next drive command value output to the drive means, and is a drive command value based on an absolute value of the difference between a target aperture value of the aperture means and an actual aperture value of the aperture means, and the aperture means is driven using the drive command value corresponding to the target aperture value .

An imaging device according to another aspect of the present invention includes the lens device, an imaging element that photoelectrically converts an optical image formed through the lens device, and a camera body that holds the imaging element.

Other objects and features of the present invention are described in the following embodiments.

The present invention provides a lens device and an imaging device that can control the aperture means at high speed and with high precision in microstep driving.

5 is a graph showing actual aperture values before and after correction in the first embodiment. FIG. 2 is a block diagram showing a configuration of an imaging device in each embodiment. 5 is a graph showing a drive instruction amount and a drive frequency in each embodiment. 4 is a graph showing a method for setting a correction value in the first embodiment. 10 is a graph showing a method for setting a correction value in the second embodiment. 10 is a graph showing an actual aperture value after correction in the second embodiment.

The following describes in detail an embodiment of the present invention with reference to the drawings.

First Embodiment
First, an overview of an image capture device (camera system) according to this embodiment will be described with reference to Fig. 2. Fig. 2 is a block diagram showing the configuration of a lens-interchangeable single-lens reflex camera as an image capture device 10 according to this embodiment.

As shown in FIG. 2, the imaging device 10 has a camera body 100 that holds an imaging means (imaging element, imaging unit) 102, and an interchangeable lens (lens device) 200 that can be attached to and detached from the camera body 100. Note that in this embodiment, the imaging device 10 as an optical device includes the interchangeable lens 200 and the camera body 100, but an interchangeable lens alone (lens device) equipped with an aperture mechanism (aperture means, aperture unit) 204 may also be treated as an optical device. Also, in this embodiment, an interchangeable lens single-lens reflex camera is described as the imaging device 10, but the present invention is also applicable to a lens-integrated camera in which the camera body and lens device are integrally configured.

In the interchangeable lens 200, 201 is a first lens unit, 202 is a focus lens unit, 203 is a variable magnification lens unit, and 204 is an aperture mechanism (aperture means). The first lens unit 201, the focus lens unit 202, the variable magnification lens unit 203, and the aperture mechanism 204 constitute an imaging optical system.

The aperture mechanism 204 has a plurality of aperture blades (not shown), an opening/closing mechanism (not shown) that opens and closes the plurality of aperture blades, and an aperture driving means 205 as a driving means (driving unit) that drives the opening/closing mechanism. The aperture mechanism 204 is a so-called iris diaphragm in which a portion of the plurality of aperture blades arranged around the optical axis OA overlaps with each other to form an aperture opening on the optical axis OA. The aperture value (F value) increases or decreases depending on the position of the plurality of aperture blades, and the overlap amount of the plurality of aperture blades also changes depending on the position of the plurality of aperture blades, and the operating load applied to the aperture driving means 205 also changes. In general, the operating load is large on the side with a large aperture value, that is, on the side where the overlap amount of the plurality of aperture blades increases. The aperture driving means 205 is composed of a stepping motor, and its driving is controlled by the lens CPU 206 as a control means (control unit) described later. The aperture mechanism 204 can be driven in a first driving direction from the open side to the small aperture side, and in a second driving direction from the small aperture side to the open side.

207 is a focus position detection means (position detection unit) that detects the position of the focus lens unit 202. The lens CPU 206 transmits and receives various information to and from the camera CPU 106 via a lens communication means (communication unit) 208 and a camera communication means (communication unit) 108, and controls the overall operation of the interchangeable lens 200 in conjunction with the camera CPU 106. The focus drive means 209 is composed of a stepping motor, a vibration motor, or the like, and moves the focus lens unit 202 in a direction along the optical axis OA (optical axis direction) via a focus drive mechanism (not shown).

The lens CPU 206 controls the driving of the focus driving means 209. Specifically, the lens CPU 206 controls the driving direction of the focus driving means 209 by changing the polarity of the focus driving signal applied to the focus driving means 209, and controls the driving instruction value of the focus driving means 209 by increasing or decreasing the number of pulses of the focus driving signal. This allows the amount of movement of the focus lens unit 202 in the optical axis direction to be controlled. At this time, the lens CPU 206 refers to focus position information from the focus lens position detection means 207. The lens CPU 206 also controls the driving (rotation direction and driving instruction value) of the aperture driving means 205. Specifically, the lens CPU 206 controls the driving direction of the aperture driving means 205 by changing the polarity of the aperture driving signal applied to the aperture driving means 205, and controls the driving instruction value of the aperture driving means 205 by increasing or decreasing the number of pulses of the aperture driving signal. This controls the amount of opening and closing of the multiple aperture blades in the aperture mechanism 204.

210 is a shooting mode switching means (mode switching unit) operated by the user to switch between a still image shooting mode and a video shooting mode. In this embodiment, the shooting mode switching means 210 is provided in the interchangeable lens 200, but it may be provided in the camera body 100. 211 is a storage means (memory such as ROM, storage unit). The storage means 211 stores a drive instruction value for the focus lens unit 202. The storage means 211 also stores data on the target aperture value and the actual aperture value at the drive instruction value according to the drive direction of the aperture mechanism 204, and information on the drive frequency according to the drive instruction amount. The drive direction of the aperture mechanism 204 is a first drive direction from the open side to the small aperture side, and a second drive direction from the small aperture side to the open side. The drive instruction value is a first drive instruction value used when driving in the first drive direction, and a second drive instruction value used when driving in the second drive direction. The drive instruction amount is the difference between the drive instruction value corresponding to the current aperture value of the aperture mechanism 204 and the drive instruction value for driving to a new drive instruction value output to the aperture drive means 205. The maximum drive instruction amount is the drive amount by which the aperture mechanism 204 can be driven from the open side to the small aperture side.

When driving the aperture mechanism 204 in a first driving direction, the lens CPU 206 controls the aperture driving means 205 by outputting a driving command based on the target aperture value, the current aperture value, and the first driving instruction value to the aperture driving means 205. When driving the aperture mechanism 204 in a second driving direction, the lens CPU 206 controls the aperture driving means 205 by outputting a driving command based on the target aperture value, the current aperture value, and the second driving instruction value to the aperture driving means 205. The lens CPU 206 determines a correction value _QN from the relationship between the target aperture value and the actual aperture value of the aperture mechanism 204. A method of controlling the aperture mechanism 204 using the correction value _QN will be described later.

Each data stored in the memory means 211 can be read out by the lens CPU 206 at any time. Light from the subject 300 (subject light) passes through the imaging optical system in the interchangeable lens 200 and enters the camera body 100. In the camera body 100, the subject light forms a subject image on the imaging means 102 with the quick return mirror 101 retracted from the optical path. The imaging means 102 is composed of a photoelectric conversion element (imaging element) such as a CCD sensor or a CMOS sensor, and photoelectrically converts the subject image (optical image) formed through the imaging optical system. When the quick return mirror 101 is arranged in the optical path, the subject light is reflected by the quick return mirror 101 and directed to the pentaprism 103. The subject light reflected by the pentaprism 103 passes through the viewfinder optical system 104 and is directed to the user's eye. This allows the user to visually recognize the subject image.

The mirror control means 105 controls the up/down operation of the quick return mirror 101 based on a control signal from the camera CPU 106. The photometry means 107 calculates the subject brightness from the output signal of the imaging means 102 or a video signal generated by an image processing circuit (not shown) described later, and outputs this as photometry information to the camera CPU 106. In the still image shooting mode, the focus detection means 109 detects the focus state of the imaging optical system by a phase difference detection method using the subject light reflected by a sub-mirror (not shown) provided behind the quick return mirror 101. The focus detection means 109 then outputs focus information indicating the focus state to the camera CPU 106. Based on the focus information, the camera CPU 106 controls the position of the focus lens unit 202 via the focus drive means 209 to obtain a focused state.

In addition, in the video shooting mode, the camera CPU 106 generates contrast information indicating the contrast state of the image from a video signal generated by an image processing circuit described later. Then, based on the contrast information, the camera CPU 106 controls the position of the focus lens unit 202 to obtain a focused state. Based on the photometry state, the camera CPU 106 also calculates the aperture value to be set in the aperture mechanism 204 and the operating speed of a shutter (not shown) that controls the exposure amount of the imaging means 102 in the still image shooting mode.

The release switch means 110 outputs a SW1 signal when the user presses the switch halfway (SW1 ON), and outputs a SW2 signal when the user presses the switch all the way (SW2 ON). The camera CPU 106 starts still image shooting preparation operations such as photometry and focus detection in response to the input of the SW1 signal, and starts shooting a still image for recording in response to the input of the SW2 signal. The video recording switch means 111 starts shooting a video for recording in response to the input of a video recording start signal each time it is operated by the user, and stops the shooting operation in response to the input of a video recording stop signal. In this embodiment, the video recording switch means 111 is provided separately from the release switch means 110, but the release switch means 110 may also function as the video recording switch means.

The image processing circuit amplifies and performs various image processing on the image signal output from the imaging means 102 to generate a digital video signal. The camera CPU 106 uses the digital video signal to generate a still image for recording, a video for display, and a video for recording. The video for display is displayed as an electronic viewfinder image on the display means 112, which includes a display element such as an LCD panel. The recording device 113 records the still image for recording and the video for recording on a recording medium such as a semiconductor memory. 114 is the power supply for the camera body 100.

Next, a method of calculating a correction value _QN1 from the relationship between the target aperture value and the actual aperture value in the drive instruction value according to the drive direction of the aperture mechanism 204 of this embodiment and controlling the aperture mechanism 204 using the correction value _QN1 will be described. The storage unit 211 stores target aperture values corresponding to the drive instruction value for each drive direction of the aperture mechanism 204, which are given from the lens CPU 206 to the aperture drive unit 205. In this embodiment, an example of unidirectional drive from the open side to the small aperture side (an example of unidirectional drive in a first drive direction: FIG. 1) will be described.

Figure 3 is a graph showing an example of the drive frequency corresponding to each drive instruction amount when driving the aperture mechanism 204 with acceleration drive and deceleration drive. The horizontal axis of Figure 3 shows the drive instruction amount (number of steps), and the vertical axis shows the drive frequency (pps). The storage means 211 stores information on the drive frequency corresponding to each drive instruction amount of the aperture mechanism 204. As shown as drive instruction amount A and drive instruction amount B in the graph of Figure 3, the drive frequency used to drive the aperture mechanism 204 differs depending on the drive instruction amount. As described above, the drive frequency used to drive the aperture mechanism 204 differs between the drive instruction amount A and the drive instruction amount B, which are different from each other. For this reason, if the aperture mechanism 204 is driven directly with the drive instruction amounts A and B, variation in aperture precision (actual aperture value) occurs.

Therefore, in this embodiment, the lens CPU 206 measures the actual aperture value Fno _CLOSE corresponding to the drive instruction value in the drive direction (first drive direction) from the open side to the small aperture side of the diaphragm mechanism 204 for each drive instruction amount, and stores it in the storage unit 211. Next, the lens CPU 206 measures the actual aperture value Fno _OPEN corresponding to the drive instruction value in the drive direction (second drive direction) from the small aperture side to the open side of the diaphragm mechanism 204 for each drive instruction amount, and stores it in the storage unit 211. The lens CPU 206 compares the actual aperture value Fno _CLOSE and Fno _OPEN for each drive instruction amount for the drive instruction value of the diaphragm mechanism 204 for each drive direction with the target aperture value corresponding to the drive instruction value for each drive direction already stored in the storage unit 211. Then, the lens CPU 206 extracts the drive instruction value that minimizes the absolute difference between the two aperture values, and stores this in the storage unit 211 as a new drive instruction value (correction value Q _N1 ).

Here, the lens CPU 206 may extract a drive instruction value where the absolute difference between both aperture values (absolute value of the difference) is within an allowable range determined by the required accuracy, i.e., equal to or less than a specific threshold value, and store this as a new drive instruction value (correction value Q _N1 ) in the storage means 211. Hereinafter, an example will be described in which the lens CPU 206 extracts a drive instruction value where the absolute difference between both aperture values is the smallest, and stores this in the storage means 211 as a new drive instruction value.

Next, a method for extracting a drive instruction value that is the basis of the correction value _QN1 will be described with reference to Fig. 4. Fig. 4 is a graph showing a method for setting the correction value _QN1 in this embodiment. In Fig. 4, the horizontal axis indicates the drive instruction value, and the vertical axis indicates the amount of light. The amount of light may be either the amount of light that passes through an opening formed by the diaphragm blades when the diaphragm mechanism 204 is driven, or the amount of light that passes through including the imaging optical system of the interchangeable lens 200. Fig. 4 shows the amount of light that passes through including the imaging optical system of the interchangeable lens 200.

In FIG. 4, the solid line plots the relationship between the amount of light corresponding to each target aperture value and the corresponding drive instruction value. The other lines plot the amount of light (corresponding to the actual aperture value) passing through the interchangeable lens 200 including the imaging optical system when the aperture mechanism 204 is driven to the drive instruction value for each of the drive instruction amounts 2, 4, 8, and 12. Here, the target drive instruction value of the amount of light corresponding to the target aperture value and the amount of light when the aperture mechanism 204 is actually driven with each drive instruction amount are shown. For the reasons described above, when comparing the amount of light corresponding to the same target aperture value, the target drive instruction value and each drive instruction value driven with each drive instruction amount do not match each other, and there is a variation. In the example shown in FIG. 4, the amount of light tends to be dark for each drive instruction value driven with any drive instruction amount for the target aperture value. Therefore, in order to drive the aperture mechanism 204 so that the amount of light is equivalent to the target aperture value, a correction value _QN1 is required.

In this embodiment, the actual aperture value Fno _CLOSE corresponding to the drive instruction value is compared with the target aperture value for each drive instruction amount, and the drive instruction value that minimizes the absolute difference between the two aperture values is extracted. For example, for the target aperture value shown in FIG. 4, the correction value when the diaphragm mechanism 204 is driven to each drive instruction value with a drive instruction amount of 2 is QN1 ₍₂₎ . By performing this extraction of the drive instruction value for all target aperture values for each drive instruction amount, the extraction of the correction value _QN1(2) is completed. In addition, this extraction is also performed for drive instruction amounts 4, 8, and 12, and all the remaining drive instruction amounts corresponding to the drive amount of the diaphragm mechanism 204, and this correction value _QN1 is stored in the storage unit 211. Thereafter, the diaphragm mechanism 204 is operated with this new drive instruction value _QN1 .

The lens CPU 206 also compares the target aperture value with the actual aperture value. When the target aperture value is in the first drive direction of the actual aperture value, a first drive instruction value of the actual aperture value that minimizes the absolute difference between the target aperture value and the actual aperture value Fno _CLOSE is calculated for each drive instruction amount, and is set as the first drive instruction value of the target aperture value. On the other hand, when the target aperture value is in the second drive direction of the actual aperture value, a second drive instruction value of the actual aperture value that minimizes the absolute difference between the target aperture value and the actual aperture value Fno _OPEN is calculated for each drive instruction amount, and is set as the second drive instruction value of the target aperture value. Then, a drive instruction value that minimizes the absolute difference between both aperture values is extracted, and this is stored in the storage unit 211 as a new drive instruction value Q _N1 .

Next, referring to FIG. 1, the actual aperture value before and after applying the correction value Q _N1 to the aperture mechanism 204 in this embodiment will be described. FIG. 1 is a graph showing the actual aperture value before and after the correction in this embodiment (before and after applying the correction value Q _N1 ). FIG. 1(a) shows the graph before the correction (before applying the correction value Q _N1 ), and FIG. 1(b) shows the graph after the correction (after applying the correction value Q _{N1 )} . In FIGS. 1(a) and 1(b), the horizontal axis shows the drive instruction value, and the vertical axis shows the actual aperture value. The actual aperture value indicates that the aperture value becomes smaller (the amount of light passing through the aperture aperture increases) as the error in the + direction of the graphs in FIGS. 1(a) and 1(b) becomes larger. Also, the actual aperture value indicates that the aperture value becomes larger (the amount of light passing through the aperture aperture decreases) as the error in the - direction becomes larger.

The horizontal axis of FIG. 1(a) is the drive instruction value in the first drive direction from the open side to the small aperture side, and the zero line of the vertical axis indicates the target aperture value. In the example of FIG. 1, the drive instruction amount is changed to 1, 2, 4, 8, and 12 for the drive instruction value. In the graph (FIG. 1 (a)) of the actual aperture value before applying the correction value Q _N1 of this embodiment, the actual aperture value varies with respect to the target aperture value depending on the drive instruction amount. And FIG. 1(b) is a graph of the actual aperture value in which the correction value Q _N1 of this embodiment is applied to drive the aperture mechanism 204, and a highly accurate aperture mechanism close to the target aperture value can be realized. In this example, the aperture accuracy is already high before the correction value Q _N1 is applied, but if the correction value Q _N1 of this embodiment is used, it is possible to further improve the aperture accuracy. In this embodiment, although the explanation is omitted, since this correction value Q _N1 is obtained according to the drive direction, it can be similarly applied to the second drive direction from the small aperture side to the open side.

The storage unit 211 stores at least one of information on the attitude (attitude difference), drive frequency, and temperature of the interchangeable lens 200 (imaging device 10) in the relationship between the drive instruction value and the actual aperture value of the aperture mechanism 204 according to the drive direction of the aperture mechanism 204. The lens CPU 206 can read out this information at any time. Here, the aperture drive unit 205 controls the drive of the aperture mechanism 204 based on at least one of information on the attitude (attitude difference), drive frequency, and temperature in the relationship between the drive instruction value and the actual aperture value of the aperture mechanism 204 according to the drive direction of the aperture mechanism 204 stored in the storage unit 211. This makes it possible to apply the correction value _QN1 even in the case of attitude differences, various drive frequencies, and temperature environments.

Thus, in this embodiment, the lens device (interchangeable lens 200) has an aperture means (aperture mechanism 204), a driving means (aperture driving means 205), a storage means 211, and a control means (lens CPU 206). The driving means drives the aperture means. The storage means 211 stores a driving instruction value (correction value Q _N1 ) for driving the aperture means from the current aperture value to the target aperture value. The control means controls the driving means based on the driving instruction value. The driving instruction value is a driving instruction value (correction value Q N1 (2), Q _{N1 (4)} , Q N1 (8), Q N1 ( ₁₂₎ ) that is set for each driving instruction amount (for example, driving instruction amounts 2, 3, _8, and ₁₂ in FIG. 4 ) and that has the smallest absolute difference between the target aperture value and the actual aperture value. Here, the multiple driving instruction values correspond to multiple plots on the graph of each driving instruction amount shown in FIG. 4 . Preferably, the drive instruction value is set for each drive instruction amount by comparing the target aperture value and the actual aperture value for a plurality of drive instruction values (by comparing the target aperture value with a plurality of plots on a graph for each drive instruction amount).

As a result, it is possible to improve aperture precision while maintaining high speed, even when the aperture is driven using micro-step acceleration and deceleration drive.

Second Embodiment
Next, a second embodiment of the present invention will be described. The basic configuration of the image pickup apparatus of this embodiment is similar to that of the image pickup apparatus 10 described in the first embodiment with reference to FIG. 2, and therefore the description thereof will be omitted.

In this embodiment, the lens CPU 206 obtains a correction value _QN2 from the relationship between the target aperture value and the actual aperture value in the drive instruction value according to the drive direction of the aperture mechanism 204, and controls the aperture mechanism 204 using the correction value _QN2 . The storage unit 211 stores target aperture values corresponding to the drive instruction value for each drive direction given from the lens CPU 206 to the aperture drive unit 205 in the aperture mechanism 204. In this embodiment, an example of unidirectional drive from the open side to the small aperture side (an example of unidirectional drive in a first drive direction: FIG. 6) will be described.

As shown in FIG. 3, the drive frequency used to drive the aperture mechanism 204 differs between the drive instruction amounts A and B. For this reason, if the aperture mechanism 204 is driven directly using the drive instruction amounts A and B, variations in aperture precision (actual aperture value) will occur.

Therefore, in this embodiment, the lens CPU 206 measures the actual aperture value Fno _CLOSE corresponding to the drive instruction value in the drive direction (first drive direction) from the open side to the small aperture side of the diaphragm mechanism 204 for each drive instruction amount, and stores it in the storage unit 211. Next, the lens CPU 206 measures the actual aperture value Fno _OPEN corresponding to the drive instruction value in the drive direction (second drive direction) from the small aperture side to the open side of the diaphragm mechanism 204 for each drive instruction amount, and stores it in the storage unit 211. The lens CPU 206 compares the actual aperture values Fno _CLOSE and Fno _OPEN corresponding to the drive instruction value of the diaphragm mechanism 204 for each drive direction with the target aperture value corresponding to the drive instruction value of the diaphragm mechanism 204 for each drive direction already stored in the storage unit 211. Then, the lens CPU 206 extracts the drive instruction amount at which the absolute difference between the two aperture values is maximum. The lens CPU 206 then finds the smallest drive instruction value from among the absolute differences between the actual aperture value and the target aperture value for the extracted drive instruction amounts, and stores this as a new drive instruction value (correction value Q _N2 ) in the memory unit 211 .

Here, the lens CPU 206 can determine a drive instruction value that is within an allowable range determined by the required accuracy, that is, equal to or less than a specific threshold value, from among the absolute difference values (absolute value of the difference) of the actual aperture value relative to the target aperture value in the extracted drive instruction amount. The lens CPU 206 may then store the drive instruction value thus determined as a new drive instruction value (correction value Q _N2 ) in the storage unit 211. Hereinafter, an example will be described in which the lens CPU 206 determines a minimum drive instruction value from among the absolute difference values of the actual aperture value relative to the target aperture value in the extracted drive instruction amount, and stores this in the storage unit 211 as a new drive instruction value. Thereafter, the lens CPU 206 operates the aperture mechanism 204 with this new drive instruction value Q _N2 .

The lens CPU 206 also compares the target aperture value with the actual aperture value. When the target aperture value is in the first drive direction of the actual aperture value, the lens CPU 206 extracts a drive instruction amount that maximizes the absolute difference between the target aperture value and the actual aperture value Fno _CLOSE . The lens CPU 206 then obtains a first drive instruction value for the actual aperture value that is the smallest among the absolute differences between the target aperture value and the actual aperture value in the extracted drive instruction amount, and sets this as the first drive instruction value for the target aperture value. The lens CPU 206 also obtains a similar value when the target aperture value is in the second drive direction of the actual aperture value, and sets this as the second drive instruction value for the target aperture value.

Next, a method for extracting a drive instruction value that is the basis of the correction value _QN2 will be described with reference to Fig. 5. Fig. 5 is a graph showing a method for setting the correction value _QN2 in this embodiment. In Fig. 5, the horizontal axis indicates the drive instruction value, and the vertical axis indicates the amount of light. The amount of light may be either the amount of light that passes through an opening formed by the diaphragm blades when the diaphragm mechanism 204 is driven, or the amount of light that passes through including the imaging optical system of the interchangeable lens 200. Fig. 5 shows the amount of light that passes through including the imaging optical system of the interchangeable lens 200.

In FIG. 5, the solid line plots the relationship between the amount of light corresponding to each target aperture value and the corresponding drive instruction value. The other lines plot the amount of light (corresponding to the actual aperture value) passing through the imaging optical system of the interchangeable lens 200 when the aperture mechanism 204 is driven to the drive instruction value for each of the drive instruction amounts 2, 4, 8, and 12. Here, the target drive instruction value of the amount of light corresponding to the target aperture value and the amount of light when the aperture mechanism 204 is actually driven with each drive instruction amount are shown. For the reasons described above, when comparing the amount of light corresponding to the same target aperture value, the target drive instruction value and each drive instruction value driven with each drive instruction amount do not match each other, and there is a variation. In the example shown in FIG. 5, the amount of light tends to be dark in each drive instruction value driven with any drive instruction amount for the target aperture value. Therefore, in order to drive the aperture mechanism 204 so that the amount of light is equivalent to the target aperture value, a correction value _QN2 is required.

In this embodiment, the actual aperture value Fno _CLOSE according to the drive instruction value is compared with the target aperture value for each drive instruction amount, and the drive instruction value with the maximum absolute difference between the two aperture values is extracted. Then, the drive instruction value with the minimum absolute difference between the actual aperture value and the target aperture value in the extracted drive instruction amount is extracted. For example, in FIG. 5, the absolute difference between the light amount corresponding to the target aperture value and each drive instruction value driven with drive instruction amounts 2, 4, 8, and 12 (maximum absolute difference) is shown by a bold (solid line) square S. Here, the comparison with the light amount corresponding to the target aperture value is set to 13 squares S for ease of explanation. The number of squares S to be compared is not limited to this as long as it can be extracted. This absolute difference (maximum absolute difference) increases or decreases at a certain drive instruction value, and the drive instruction amount (drive instruction amount corresponding to the maximum value) differs (can differ) depending on the drive instruction value.

Next, the drive instruction value of the drive instruction amount that is the smallest among the absolute differences between the actual aperture value and the target aperture value for this extracted drive instruction amount (the drive instruction value corresponding to the smallest maximum among the maximums of the extracted absolute differences) is extracted as a correction value _QN2 . In the first embodiment, this extraction is also performed for drive instruction amounts 4, 8, and 12, and all of the remaining drive instruction amounts corresponding to the drive amounts of the aperture mechanism 204, but in this embodiment, this is not performed and the correction value _QN2 is stored in the storage means 211.

Thereafter, the diaphragm mechanism 204 is operated with this new drive instruction value Q _N2 . That is, the lens CPU 206 measures the actual aperture value of the diaphragm mechanism 204 using a measuring means (not shown), and measures the actual aperture value of the diaphragm mechanism 204 while reciprocating the diaphragm mechanism 204 based on the drive command (drive instruction value). In this way, the lens CPU 206 acquires the first drive instruction value and the second drive instruction value stored in the storage means 211. The lens CPU 206 also compares the target aperture value with the actual aperture value. When the target aperture value is in the first drive direction of the actual aperture value, the lens CPU 206 extracts a drive instruction amount that maximizes the absolute value of the difference between the target aperture value and the actual aperture value Fno _CLOSE . The lens CPU 206 then obtains a first drive instruction value of the actual aperture value that is the smallest among the absolute values of the difference between the actual aperture value and the target aperture value in the extracted drive instruction amount, and sets this as the first drive instruction value of the target aperture value. The lens CPU 206 also obtains a similar value when the target aperture value is in the second drive direction of the actual aperture value, and sets this as the second drive instruction value of the target aperture value.

Next, referring to FIG. 6, the actual aperture value after applying the correction value Q _N2 to the aperture mechanism 204 in this embodiment will be described. FIG. 6 is a graph showing the actual aperture value after correction (after applying the correction value Q _N2 ) in this embodiment. In FIG. 6, the vertical axis shows the actual aperture value, and indicates that the larger the error in the + direction of the graph, the smaller the aperture value (the more light passes through the aperture opening), and the larger the error in the - direction, the larger the aperture value (the less light passes through the aperture opening). The horizontal axis shows the drive instruction value in the first drive direction from the open side to the small aperture side, and the zero line on the vertical axis shows the target aperture value. In the example of FIG. 6, the drive instruction amount is changed to 1, 2, 4, 8, and 12 for the drive instruction value. The graph of the actual aperture value before applying the correction value Q _N2 in this embodiment is as shown in FIG. 1(a).

6 is a graph of the actual aperture value when the aperture mechanism 204 is driven by applying the correction value _QN2 of this embodiment, and shows that an aperture mechanism closer to the target aperture value can be realized compared to FIG. 1A. In this embodiment, not only can an aperture mechanism closer to the target aperture value be realized by applying the correction value _QN2 , but the amount of information stored in the storage unit 211 can be reduced compared to the first embodiment.

Specifically, in the first embodiment, an actual aperture value Fno _CLOSE corresponding to a drive instruction value in a drive direction (first drive direction) from the open side to the small aperture side of the diaphragm mechanism 204 is measured for each drive instruction amount, and stored in the storage unit 211. Also in the first embodiment, a first drive instruction value for an actual aperture value that minimizes the absolute difference between a target aperture value previously stored in the storage unit 211 and the actual aperture value Fno _CLOSE is obtained for each drive instruction amount. Then, it is necessary to store a plurality of patterns corresponding to drive amounts from the open side to the small aperture side of the diaphragm mechanism 204 as the first drive instruction value for each target aperture value.

On the other hand, in this embodiment, the target aperture value stored in the storage unit 211 in advance is compared with the actual aperture value, but only one pattern needs to be stored as the first drive instruction value corresponding to the target aperture value. This allows the amount of information stored in the storage unit 211 to be reduced. In this embodiment, the aperture precision is already high before the correction value _QN2 is applied, but the correction value _QN2 can be used to further improve the aperture precision. In this embodiment, the correction value _QN2 can be obtained according to the drive direction, so it can be similarly applied to the second drive direction from the small aperture side to the open aperture side. In addition, the storage unit 211 stores at least one piece of information on the attitude (attitude difference), drive frequency, and temperature of the interchangeable lens 200 (imaging device 10) in the relationship between the drive instruction value of the aperture mechanism 204 according to the drive direction of the aperture mechanism 204 and the actual aperture value. The lens CPU 206 can read out this information at any time. The aperture driving unit 205 controls the driving of the aperture mechanism 204 based on at least one of information on the attitude (attitude difference), driving frequency, and temperature in the relationship between the driving instruction value and the actual aperture value of the aperture mechanism 204 according to the driving direction of the aperture mechanism 204 stored in the storage unit 211. This makes it possible to apply the correction value _QN2 even in the presence of attitude differences, various driving frequencies, and temperature environments.

Thus, in this embodiment, the lens device (interchangeable lens 200) has an aperture means (aperture mechanism 204), a driving means (aperture driving means 205), a storage means 211, and a control means (lens CPU 206). The driving means drives the aperture means. The storage means 211 stores a driving instruction value (correction value Q _N2 ) for driving the aperture means from the current aperture value to the target aperture value. The control means controls the driving means based on the driving instruction value. The driving instruction value (correction value Q _N2 ) is a driving instruction value for which the absolute difference between the target aperture value and the actual aperture value is the smallest among a plurality of driving instruction values in a driving instruction amount for which the absolute difference between the target aperture value and the actual aperture value is the largest. Here, the plurality of driving instruction values in a driving instruction amount for which the absolute difference between the target aperture value and the actual aperture value is the largest correspond to the driving instruction values for driving the aperture mechanism 204 shown in the 13 solid-line squares S shown in FIG. 5 to each position. That is, the seven squares S on the left side of Fig. 5 represent the differences between the actual aperture value and the target aperture value when the diaphragm mechanism 204 is driven with each of the drive instruction values shown in the seven squares S on the left side at a drive instruction amount of 8. Also, the six squares S on the right side of Fig. 5 represent the differences between the actual aperture value and the target aperture value when the diaphragm mechanism 204 is driven with each of the drive instruction values shown in the six squares S on the right side at a drive instruction amount of 12.
The drive instruction value for which the absolute difference between the target aperture value and the actual aperture value is the smallest is the drive instruction value for the drive instruction amount corresponding to the square with the smallest length among the 13 squares S shown in Fig. 5. Preferably, the drive instruction value is set by comparing the target aperture value and the actual aperture value for a plurality of drive instruction values for each drive instruction amount, and extracting, for each of the plurality of drive instruction values, the drive instruction amount for which the absolute difference between the target aperture value and the actual aperture value is the largest.

As a result, it is possible to improve aperture precision while maintaining high speed, even when the aperture is driven using micro-step acceleration and deceleration drive.

In each embodiment, the aperture means is preferably capable of being driven in a first drive direction from the open aperture side to the small aperture side and in a second drive direction from the small aperture side to the open aperture side. The storage means stores, as drive instruction values, a first drive instruction value used when driving the aperture means in the first drive direction and a second drive instruction value used when driving the aperture means in the second drive direction. The control means controls the drive means based on the first drive instruction value when the target aperture value is in the first drive direction relative to the current aperture value. The control means also controls the drive means based on the second drive instruction value when the target aperture value is in the second drive direction relative to the current aperture value.

Preferably, the drive instruction amount is the difference between the drive instruction value corresponding to the current aperture value of the aperture means and the next drive instruction value output to the drive means. Also preferably, the drive means drives the aperture means by microstep drive (drive using a sine wave signal and a cosine wave signal) to perform acceleration drive and deceleration drive. Also preferably, the storage means stores data indicating the relationship between the drive instruction value and the actual aperture value. More preferably, the storage means stores data for at least one piece of information of the attitude of the lens device, the drive frequency, and the temperature. More preferably, the control means outputs to the drive means a drive instruction value based on at least one piece of information of the attitude of the lens device, the drive frequency, and the temperature.

In each embodiment, a stepping motor is used for the aperture drive means 205, but the present invention is not limited to this. For example, a DC motor, a linear motor, an ultrasonic motor, etc. may be used as the aperture drive means 205.

According to each embodiment, it is possible to provide a lens device and an imaging device that can control the aperture means at high speed and with high precision in microstep driving.

The above describes preferred embodiments of the present invention, but the present invention is not limited to these embodiments, and various modifications and variations are possible within the scope of the gist of the invention.

200 Interchangeable lenses (lens devices)
204 Throttle mechanism (throttle means)
205 Aperture driving means (driving means)
206 Lens CPU (control means)
211 Memory (storage means)

Claims (11)

A throttling means;
A driving means for driving the diaphragm means;
a storage means for storing a drive instruction value for driving the aperture means;
a control means for controlling the driving means based on the drive instruction value,
The drive instruction value is
a drive instruction value set corresponding to a drive instruction amount that is a difference between a drive instruction value corresponding to a current aperture value of the aperture means and a next drive instruction value output to the drive means,
a drive instruction value based on an absolute value of a difference between a target aperture value of the aperture means and an actual aperture value of the aperture means,
a lens device that drives the aperture means using the drive instruction value corresponding to the target aperture value; The lens device according to claim 1, characterized in that the drive instruction value is a drive instruction value that is set for each of the drive instruction amounts and that has the smallest absolute value of the difference between the target aperture value and the actual aperture value. The lens device according to claim 1, characterized in that the drive instruction value is a drive instruction value among a plurality of drive instruction values set for each of the drive instruction amounts, the absolute value of the difference between the target aperture value and the actual aperture value being equal to or less than a threshold value. The drive instruction value is
2. The lens device according to claim 1, wherein, among a plurality of drive instruction values in a drive instruction amount in which the absolute value of the difference between the target aperture value and the actual aperture value is maximized, the drive instruction value is the drive instruction value in which the absolute value of the difference between the target aperture value and the actual aperture value is the smallest. The drive instruction value is
5. The lens device according to claim 4, wherein, for each of the drive instruction amounts, the target aperture value and the actual aperture value are compared for the multiple drive instruction values, and a drive instruction amount that maximizes an absolute value of a difference between the target aperture value and the actual aperture value is extracted for each of the multiple drive instruction values. the throttling means is drivable in a first drive direction from an open side to a small throttling side and in a second drive direction from the small throttling side to the open side,
the storage means stores, as the drive instruction value, a first drive instruction value used when driving the diaphragm means in the first drive direction and a second drive instruction value used when driving the diaphragm means in the second drive direction;
The control means
When the target aperture value is in the first drive direction with respect to the current aperture value of the aperture means, the drive means is controlled based on the first drive instruction value;
6. The lens device according to claim 1, wherein when the target aperture value is in the second drive direction with respect to the current aperture value, the drive means is controlled based on the second drive instruction value. 7. The lens device according to claim 1, wherein the driving means drives the diaphragm means by micro-step driving, and performs acceleration driving and deceleration driving. 8. The lens device according to claim 1, wherein the storage means stores data indicating a relationship between the drive instruction value and an actual aperture value of the aperture means. 9. The lens device according to claim 8 , wherein the storage means stores the data for at least one piece of information of the attitude, the drive frequency, and the temperature of the lens device. 10. The lens device according to claim 9 , wherein the control means outputs to the driving means the drive instruction value based on at least one of the information items of the attitude of the lens device, the drive frequency, and the temperature. A lens device according to any one of claims 1 to 10 ;
an image pickup element that photoelectrically converts an optical image formed through the lens device;
and a camera body that holds the image sensor.