JP2012198441A - Lens unit, photographing device using the lens unit, and computer program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a photographing device which can simply change an opening shape of a diaphragm, and change the opening shape of the diaphragm to an optional shape.SOLUTION: A photographing device 100 includes: an opening shape storage portion 11 for storing a plurality of opening shapes; an opening shape selecting conversion rotating portion 12 for selecting one opening shape from the plurality of the opening shapes stored in the opening shape storage portion; and a liquid crystal diaphragm 21 which is configured by a liquid crystal panel and drives a liquid crystal panel so as to make light pass therethrough in an area corresponding to the opening shape, according to the opening shape selected by the opening shape selecting conversion rotating portion 12.

Description

  The present invention relates to a lens unit having a diaphragm, a photographing apparatus using the lens unit, and a computer program.

  When taking a picture using the photographing apparatus, if the subject has a point light source and the point light source is not in focus, a photographed image in which the point light source is blurred is obtained. At this time, the blurred shape of the point light source is the aperture shape of the stop. Further, when taking a photograph using the photographing apparatus, light called a ghost may be reflected in a photographed image due to repeated reflection of strong incident light inside the lens or the camera body. This ghost shape is also the aperture shape of the stop.

  The aperture is generally circular or polygonal, but has an aperture of any shape such as a heart shape or a star shape in order to enjoy a variety of shooting expressions by changing the blur shape of the point light source or the ghost shape. A deformation aperture has also been proposed. The deformed diaphragm is a disk-shaped diaphragm and is attached to the lens so as to be replaceable. The user can select a diaphragm having a desired aperture shape from among the disk-shaped apertures, and attach the lens to the lens, thereby realizing a blur or ghost of a point light source in the aperture shape.

  In addition, there exist the following prior art documents as a prior art relevant to this invention.

JP 2003-344897 A JP 11-338002 A

  However, in the above prior art, when changing the aperture shape of the aperture, it is necessary to select a diaphragm having a desired aperture shape from among the disk-shaped apertures and attach it to the lens, which is very laborious. . Also, the types of aperture shapes that can be changed are limited to the types of disc-shaped apertures that you have, and if you want to increase the types of aperture shapes that you can change, prepare disk-shaped apertures that differ by the number of types. Must.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide an imaging apparatus that can easily change the aperture shape of the diaphragm and change the aperture shape of the aperture to an arbitrary shape.

  An imaging apparatus according to the present invention includes an opening shape storage unit for storing a plurality of opening shapes, and an opening shape selection unit that selects one opening shape from the plurality of opening shapes stored in the opening shape storage unit. And a pixel array diaphragm configured to drive the pixel array so as to transmit light in a region corresponding to the aperture shape according to the aperture shape selected by the aperture shape selection unit. have.

  According to this configuration, the aperture shape of the aperture can be realized by changing the region that transmits light in the pixel array, that is, by driving the pixel array as such, so the aperture shape of the aperture can be easily changed, Further, the aperture shape of the diaphragm can be changed to an arbitrary shape.

  In addition, the photographing apparatus of the present invention may further include an operation input unit for the user to select one opening shape from among a plurality of opening shapes stored in the opening shape storage unit. The unit may select the opening shape based on the selection of the opening shape by the user input to the operation input unit.

  According to this configuration, the user can select a desired opening shape from among a plurality of opening shapes stored in the opening shape storage unit.

  The imaging device of the present invention may further include an aperture shape rotation unit that rotates the aperture shape selected by the aperture shape selection unit, and the operation input unit can also instruct rotation of the aperture shape. The opening shape rotation unit may rotate the selected opening shape based on a rotation instruction by the user input to the operation input unit.

  According to this configuration, the user can select a desired opening shape from among a plurality of opening shapes stored in the opening shape storage unit and rotate it.

  In addition, the photographing apparatus of the present invention may further include an opening shape conversion unit that enlarges or reduces the opening shape selected by the opening shape selection unit.

  According to this configuration, the aperture ratio (that is, the aperture value) of the diaphragm can be changed by enlarging or reducing the aperture shape, and the size of the point light source (which has the aperture shape) appearing in the captured image. You can also change the size.

  In the photographing apparatus of the present invention, the operation input unit may be capable of instructing the enlargement or reduction of the opening shape, and the opening shape conversion unit may be enlarged or reduced by a user input to the operation input unit. The selected opening shape may be enlarged or reduced based on a reduction instruction.

  According to this configuration, the user can select a desired opening shape from among a plurality of opening shapes stored in the opening shape storage unit, and enlarge or reduce it.

  In addition, the photographing apparatus of the present invention includes a program photographing control unit that determines a shutter speed based on an aperture value when an aperture value is designated, and an aperture ratio calculation unit that obtains the aperture ratio of the aperture shape from the aperture value. The operation input unit can also indicate the aperture value, and the program shooting control unit determines a shutter speed based on the aperture value designated by the operation input unit, The aperture ratio calculation unit calculates an aperture ratio of the aperture shape corresponding to the aperture value specified by the operation input unit, and the aperture shape conversion unit calculates the aperture shape calculated by the aperture ratio calculation unit. The selected opening shape may be enlarged or reduced based on the opening ratio.

  According to this configuration, when the imaging apparatus performs aperture-priority programmed imaging control, the aperture shape can be enlarged or reduced so that the aperture value specified by the user is realized.

  In addition, the photographing apparatus of the present invention includes a program photographing control unit that determines an aperture value based on a shutter speed when a shutter speed is specified, and an aperture ratio calculation unit that obtains the aperture ratio of the aperture shape from the aperture value. The operation input unit can also instruct the shutter speed, and the program shooting control unit determines an aperture value based on the shutter speed specified by the operation input unit, The aperture ratio calculation unit obtains an aperture ratio of the aperture shape corresponding to the aperture value determined by the programmed photographing control unit, and the aperture shape conversion unit calculates the aperture obtained by the aperture ratio calculation unit. Based on the aperture ratio of the shape, the selected aperture shape may be enlarged or reduced.

  According to this configuration, when the photographing apparatus performs the shutter speed priority program photographing control, the aperture shape is set so that the aperture value determined by the program photographing control is realized based on the shutter speed designated by the user. Can be enlarged or reduced.

  The lens unit of the present invention is a lens unit that is attached to the photographing apparatus main body, and is configured by a pixel array so as to transmit light in a region corresponding to the designated opening shape based on the designated opening shape. And a pixel array diaphragm for driving the pixel array.

  Even with this configuration, the aperture shape of the aperture can be realized by changing the light transmitting area in the pixel array, that is, by driving the pixel array as such, so that the aperture shape of the aperture can be easily changed. The aperture shape of the diaphragm can be changed to an arbitrary shape.

  The computer program of the present invention is a computer program executed by a computer in an imaging apparatus, and the imaging apparatus includes an aperture shape storage unit for storing a plurality of aperture shapes and a pixel array. A pixel array diaphragm, and the computer program includes: an aperture shape selection step for selecting one aperture shape from a plurality of aperture shapes stored in the aperture shape storage unit; and the aperture shape selection step. The computer executes a pixel array driving step of driving the pixel array of the pixel array diaphragm so as to transmit light in a region corresponding to the aperture shape according to the selected aperture shape.

  Even with this configuration, the aperture shape of the aperture can be realized by changing the light transmitting area in the pixel array, that is, by driving the pixel array as such, so that the aperture shape of the aperture can be easily changed. The aperture shape of the diaphragm can be changed to an arbitrary shape.

  According to the present invention, the aperture shape of the aperture can be realized by changing the region that transmits light in the pixel array, that is, by driving the pixel array as such, so that the aperture shape of the aperture can be easily changed, Further, the aperture shape of the diaphragm can be changed to an arbitrary shape.

The block diagram which shows the structure of the imaging device in embodiment of this invention 1 is an external view of a photographing apparatus according to an embodiment of the present invention. The figure which showed a mode that opening shape was created by handwriting with the touchscreen in embodiment of this invention. (A) The figure which shows the example of the opening shape of the heart mark in embodiment of this invention (b) The figure which shows the example of the opening shape of the umbrella mark in embodiment of this invention (c) In embodiment of this invention The figure which shows the example of the opening shape of the character "love" (d) The figure which shows the example of the opening shape of the character of "S" input by handwriting in embodiment of this invention The figure which shows the example of the image image | photographed in focus in embodiment of this invention The figure which shows the example of the image image | photographed so that a focus may not be suitable for a to-be-photographed object, when the aperture shape of the aperture_diaphragm | restriction in embodiment of this invention is circular or a polygon close | similar to a circle. The figure which shows the example of the image image | photographed by making the opening shape of the liquid-crystal aperture stop in the embodiment of this invention into the shape of the character of "love", and a focus does not focus on a to-be-photographed object.

  Hereinafter, an imaging device according to an embodiment of the present invention will be described with reference to the drawings.

  FIG. 1 is a diagram illustrating a configuration of an imaging device 100 according to an embodiment of the present invention. In FIG. 1, only the main configuration for the embodiment of the present invention is shown, and the illustration of the other configuration is omitted. However, in the following description, the configuration that is not shown is also added as necessary. . FIG. 2 is an external view of the photographing apparatus 100 according to the embodiment of the present invention. First, the schematic configuration of the photographing apparatus 100 will be described with reference to FIG. 2, and then the configuration will be described in detail with reference to FIG.

  As shown in FIG. 2, the photographing apparatus 100 is a camera including a main body 10 and a lens unit 20. The main body 10 may be a device that takes an analog photograph using a silver salt method, or may be a device that takes a digital method using an image sensor. In the present embodiment, a case where the photographing apparatus 100 is a photographing apparatus that performs photographing using a digital method, that is, a digital camera is described as an example.

  The lens unit 20 is detachable from the main body 10. The lens unit 20 may be fixed to the main body 10. A plurality of lenses 22 are housed in the lens unit 20 so as to be movable back and forth, and a liquid crystal diaphragm 21 is included therein.

  The photographing apparatus 100 takes light from the subject into the main body 10 by the lens unit 20, converts the light from the subject into an electric signal in the main body 10, and generates image data based on the electric signal. At this time, the light passing through the lens unit 20 is stopped by the liquid crystal stop 21.

  In the present embodiment, the liquid crystal diaphragm 21 is composed of a circular liquid crystal panel. By driving the liquid crystal panel, the liquid crystal diaphragm 21 can transmit the captured light in a region having an arbitrary shape in the liquid crystal panel. In the liquid crystal panel constituting the liquid crystal diaphragm 21, the shape of the region through which the captured light is transmitted is referred to as the “opening shape” of the liquid crystal diaphragm 21. The liquid crystal diaphragm 21 corresponds to the pixel array diaphragm of the present invention, and the liquid crystal panel constituting the liquid crystal diaphragm 21 corresponds to the pixel array of the present invention.

  In the photographing apparatus 100, when the lens unit 20 is attached to the main body 10, the main body 10 and the lens unit 20 can exchange various signals. This signal includes a signal indicating information on an aperture shape for realizing a desired aperture shape in the liquid crystal diaphragm 21 in addition to a signal for driving the lens 22 for automatic focusing.

  The main body 10 is provided with various operation buttons and a liquid crystal monitor (see FIG. 3). This operation button corresponds to an operation input unit (see FIG. 1) described later, and the liquid crystal monitor corresponds to a touch panel (see FIG. 1) described later.

  Next, the configuration of the photographing apparatus 100 will be described with reference to FIG. The imaging device 100 includes an aperture shape storage unit 11, an aperture shape selection conversion rotation unit 12, an aperture ratio calculation unit 13, a program imaging control unit 14, an imaging unit 15, an image processing unit 16, an operation input unit 17, a communication unit 18, and a touch panel. 19 and a lens unit 20 are provided. The lens unit 20 includes a liquid crystal diaphragm 21 and a plurality of lenses 22.

  The aperture shape storage unit 11 stores a plurality of types of aperture shapes of the liquid crystal diaphragm 21. The opening shape selection conversion rotation unit 12 selects one opening shape from the plurality of opening shapes stored in the opening shape storage unit 11, and enlarges or reduces the selected opening shape as necessary. Convert and rotate. The opening shape selection conversion rotating unit 12 corresponds to the opening shape selection unit, the opening shape conversion unit, and the opening shape rotation unit of the present invention.

  The aperture ratio calculation unit 13 opens the aperture for the aperture shape selected by the aperture shape selection / conversion rotation unit 12 (when the enlargement / reduction conversion or rotation is performed, the enlargement / reduction conversion or the rotated aperture shape). The aperture is calculated, and the aperture value (F value) corresponding to the aperture ratio is obtained. The aperture ratio refers to the ratio of the area of a region through which light passes to the entire area of the liquid crystal diaphragm 21. The aperture ratio calculation unit 13 also calculates the aperture ratio of the diaphragm corresponding to the aperture value according to the given aperture value.

  The program control unit 14 determines shooting conditions including the aperture value of the liquid crystal diaphragm 21 and the shutter speed according to a predetermined program, and outputs a control signal to the shooting unit 15 so as to perform shooting under the determined shooting conditions. The imaging unit 15 converts light emitted from the subject and passing through the lens unit 20 into an electrical signal. The image processing unit 16 processes the electrical signal generated by the photographing unit 15 to generate image data. The image data generated by the image processing unit 16 is displayed on the liquid crystal monitor (preview display) or stored as an image file in the storage medium.

  The photographing apparatus 100 includes the operation input unit 17 as described above. The user can perform various operations on the operation input unit 17. Specifically, the user can select the opening shape of the liquid crystal diaphragm 21 by operating the operation input unit 17. The input of this operation is given to the opening shape selection conversion rotating unit 12. Further, the user can operate the operation input unit 17 to instruct enlargement / reduction conversion and rotation of the opening shape. The input of this operation is also given to the opening shape selection conversion rotating unit 12.

  Further, the user can designate photographing conditions such as an aperture value of the liquid crystal diaphragm 21 and a shutter speed of the photographing unit 15 and a photographing mode by operating the operation input unit 17. When the user specifies an aperture value with the operation input unit 17, the input is given to the aperture ratio calculation unit 13 and the program shooting control unit 14, and when the user specifies the shutter speed or shooting mode, the input is made. Is given to the program shooting control unit 14.

  The aperture shape selection conversion rotating unit 12 sends the determined aperture shape to the liquid crystal diaphragm 21 as an image signal, and the liquid crystal diaphragm 21 transmits light in a region corresponding to the determined aperture shape according to the image signal. Drive.

  As described above, various opening shapes are stored in the opening shape storage unit 11, but this opening shape may be stored in advance or may be added by the user. For this purpose, the photographing apparatus 100 includes a communication unit 18 and a touch panel 19. The communication unit 18 receives information on the opening shape from the external device through communication with the external device, and stores it in the opening shape storage unit 11.

  FIG. 3 is a diagram showing a state in which an opening shape is created by handwriting on the touch panel 19. As shown in FIG. 3, the portion traced by the user with the hand on the touch panel 19 is colored. Thus, the opening shape input by the user by handwriting on the touch panel 19 is stored in the opening shape storage unit 11.

  Further, the opening shape can be acquired by photographing. Therefore, in the photographing apparatus 100, the image data generated by the image processing unit 16 can be stored in the opening shape storage unit 11 as an opening shape. Thereby, the user can preserve | save the pattern as an opening shape by image | photographing a desired pattern.

  FIG. 4 is an example of the opening shape stored in the opening shape storage unit 11. 4A is the opening shape of the heart mark, FIG. 4B is the opening shape of the umbrella mark, FIG. 4C is the opening shape of the letters “love”, and FIG. The opening shape of the letter “S” is shown. The aperture shape storage unit 11 stores such information on the aperture shape, and the liquid crystal diaphragm 21 drives the liquid crystal panel so that light is transmitted in a region corresponding to the aperture shape according to such an aperture shape. To do.

  5 to 7 are diagrams illustrating examples of images obtained by photographing substantially the same subject. The subject of these images includes an automobile headlight or the like as a point light source. FIG. 5 is an image taken with focus. FIG. 6 shows a case where the aperture shape of the diaphragm is a circle or a polygon close to a circle, that is, when the conventional ordinary diaphragm is used or the liquid crystal diaphragm 21 of the present embodiment has a circular or nearly circular aperture shape. In the case of a polygon, this is an image taken so that the focus does not match the subject. In this image, the headlight of an automobile that was a point light source is blurred and enlarged, and the shape thereof is an aperture shape of a diaphragm (a circle or a polygon close to a circle).

  FIG. 7 shows an image taken with the aperture shape of the liquid crystal diaphragm 21 as shown in FIG. 4C in the shape of the letters “love” and with the focus not on the subject as shown in FIG. It is. In this image, the headlight of the car, which was a point light source, is blurred and large, and its shape is the letter “love”, which is the aperture shape of the stop. As described above, by making the aperture shape of the stop arbitrary, the blur shape of the point light source can be made arbitrary.

  Next, processing in the opening shape selection conversion rotating unit 12 in FIG. 1 will be described. As described above, the user can select an arbitrary opening shape from among a plurality of opening shapes stored in the opening shape storage unit 11. The user can perform enlargement / reduction conversion or rotate the opening shape read from the opening shape storage unit 11. Here, the aperture shape and its enlargement / reduction ratio affect the aperture ratio of the aperture, that is, the aperture value.

  On the other hand, the photographing apparatus 100 has a function of performing program photographing, and this program photographing is controlled by the program photographing control unit 14. The photographing apparatus 100 of the present embodiment can perform photographing in the aperture priority mode, the shutter speed priority mode, and the automatic mode as program photographing.

  In this embodiment, the aperture priority mode is a mode in which the user operates the operation input unit 17 to specify the aperture value, the type of aperture shape, and the rotation (however, the rotation can be specified arbitrarily). is there). The aperture value designated by the user is input to the aperture ratio calculation unit 13. The type and rotation of the opening shape designated by the user are input to the opening shape selection conversion rotating unit 12.

  The aperture ratio calculation unit 13 calculates an aperture ratio corresponding to the aperture value designated by the user, and outputs the calculated aperture ratio to the aperture shape selection conversion rotation unit 12. The aperture shape selection conversion rotation unit 12 selects and rotates the aperture shape according to the input from the user, and further enlarges the aperture shape selected and rotated so that the aperture ratio input from the aperture ratio calculation unit 13 is obtained. Or reduce. Note that the aperture value designated by the user is also input to the program shooting control unit 14, and the program shooting control unit 14 determines an appropriate shutter speed based on the aperture value.

  The aperture shape selected, enlarged / reduced, and rotated by the aperture shape selection / conversion rotation unit 12 is output to the liquid crystal diaphragm 21, and the liquid crystal diaphragm 21 drives the liquid crystal according to the aperture shape. The program shooting control unit 14 outputs the determined shutter speed to the shooting unit 15, and the shooting unit 15 drives the electronic shutter at this shutter speed.

  In the shutter speed priority mode of the present embodiment, the user designates the shutter speed, the type of opening shape, and the rotation by operating the operation input unit 17. The shutter speed designated by the user is input to the program shooting control unit 14. The type and rotation of the opening shape designated by the user are input to the opening shape selection conversion rotating unit 12.

  The program photographing control unit 14 calculates an appropriate aperture value based on the shutter speed designated by the user, and outputs it to the aperture ratio calculation unit 13. The aperture ratio calculation unit 13 calculates an aperture ratio corresponding to the aperture value obtained from the program control unit 14 and outputs the aperture ratio to the aperture shape selection conversion rotation unit 12.

  The opening shape selection conversion rotating unit 12 selects an opening shape according to the type of opening shape specified by the user, and performs rotation specified by the user with respect to the opening shape. Further, the opening shape selection conversion rotating unit 12 enlarges or reduces the selected and rotated opening shape based on the opening ratio calculated by the opening ratio calculation unit 13.

  The aperture shape selected, enlarged / reduced, and rotated by the aperture shape selection / conversion rotation unit 12 is output to the liquid crystal diaphragm 21, and the liquid crystal diaphragm 21 drives the liquid crystal panel according to the aperture shape. The program photographing control unit 14 outputs the shutter speed designated by the user to the photographing unit 15, and the photographing unit 15 drives the electronic shutter at this shutter speed.

  In the automatic mode of the present embodiment, the user can select an opening shape by performing an operation with the operation input unit 17, and can instruct the enlargement / reduction and rotation of the opening shape. Instructions for enlargement / reduction and rotation of the type of opening shape specified by the user are input to the opening shape selection conversion rotation unit 12. The opening shape selection conversion rotating unit 12 selects an opening shape in accordance with an input from the user, rotates it, and enlarges or reduces it.

  The aperture ratio calculation unit 13 calculates the aperture ratio of the aperture shape that has been selected, enlarged, reduced, and rotated by the aperture shape selection conversion rotation unit 12, and obtains an aperture value corresponding to the calculated aperture ratio. This is output to the program shooting control unit 14. The program control unit 14 determines an optimum shutter speed based on the aperture value obtained by the aperture ratio calculation unit 13.

  The aperture shape selected, enlarged / reduced, and rotated by the aperture shape selection / conversion rotation unit 12 is output to the liquid crystal diaphragm 21, and the liquid crystal diaphragm 21 drives the liquid crystal panel according to the aperture shape. The program photographing control unit 14 outputs the determined shutter speed to the photographing unit 15, and the photographing unit 15 drives the electronic shutter at this shutter speed.

  As described above, according to the photographing apparatus 100 of the present embodiment, by adopting the liquid crystal diaphragm 21, there is no need to change the disk-shaped diaphragm according to the opening shape as in the prior art, and the operation input unit 17 Any opening shape can be realized easily and quickly by the operation of. In addition, the photographing apparatus 100 according to the present embodiment employs the liquid crystal diaphragm 21 so that photographing can be performed by various methods as described below.

  Since the photographing device 100 can change the aperture shape instantaneously with the liquid crystal diaphragm 21, for example, by continuously photographing with different aperture shapes, a plurality of blur shapes of various point light sources with respect to the same subject are obtained. An image can be generated.

  In addition, since the photographing apparatus 100 is a digital photographing apparatus, the present embodiment can be applied as follows. That is, as described above, the point light source is blurred in a shape corresponding to the opening shape when it is not focused, but at this time, portions other than the point light source are also blurred. Accordingly, the liquid crystal diaphragm 21 is used as a desired aperture shape to continuously perform shooting without focusing and focused shooting, and extract only the blurred point light source from the image in which the point light source is blurred to the desired shape. Then, the focused image may be synthesized.

  Further, when the photographing apparatus 100 is a digital photographing apparatus, the image pickup unit 15 always generates a video signal, which is displayed on the monitor, and the user operates the shutter to make the video signal as an image file. A process of recording on a recording medium is performed. When the photographing apparatus 100 is performing the monitor display, the liquid crystal diaphragm 21 is displayed on the monitor screen, for example, by displaying a plurality of aperture shapes of the liquid crystal diaphragm 21 and allowing the user to select the shape. You may change the opening shape of. Thereby, the user can select the opening shape after confirming which opening shape is desirable on the monitor display.

  In the above embodiment, all the elements other than the liquid crystal diaphragm 21 and the lens 22 shown in FIG. 1 are provided in the main body 10, but even if a part of the configuration is provided in the lens unit 20. Good. For example, an aperture shape storage unit may be provided in the lens unit.

  Moreover, in said embodiment, the operation input part 17 may be comprised with a touchscreen, and may be comprised with a switch and a button. At this time, the touch panel 19 for handwriting input of the aperture shape of the diaphragm and the touch panel as the operation input unit 17 may be realized by the same touch panel.

  In the above-described embodiment, the liquid crystal diaphragm including the liquid crystal panel is described as the pixel array diaphragm. However, the pixel array diaphragm of the present invention is not limited to this. That is, the pixel array diaphragm may be any diaphragm in which a plurality of individually drivable pixels are arranged and the transmission / blocking of light can be controlled for each pixel. The pixel and its driving method are liquid crystal pixels and liquid crystal pixel driving. Not limited to. For example, the pixel array diaphragm may have a configuration in which a plurality of small EMES (Micro Electronics-Mechanical Systems) shutters are arranged as pixels.

  In addition, the aperture shape selection conversion rotation unit 12, the aperture ratio calculation unit 13, and the program shooting control unit 14 may be realized by a computer in the shooting apparatus 100 executing a computer program.

  INDUSTRIAL APPLICABILITY The present invention has an effect that the aperture shape of the aperture can be easily changed and the aperture shape of the aperture can be changed to an arbitrary shape, and is useful as a lens unit having an aperture and a photographing apparatus using the same. .

DESCRIPTION OF SYMBOLS 10 Main body 11 Aperture shape preservation | save part 12 Aperture shape selection conversion rotation part 13 Aperture ratio calculation part 14 Program imaging | photography control part 15 Imaging | photography part 16 Image processing part 17 Operation input part 18 Communication part 19 Touch panel 20 Lens unit 21 Liquid crystal diaphragm 22 Lens 100 Photographing apparatus

Claims (9)

An opening shape storage unit for storing a plurality of opening shapes;
An opening shape selection unit that selects one opening shape from a plurality of opening shapes stored in the opening shape storage unit;
A pixel array diaphragm configured to drive the pixel array so as to transmit light in a region corresponding to the aperture shape, according to the aperture shape selected by the aperture shape selection unit;
An imaging apparatus comprising: The apparatus further comprises an operation input unit for the user to select one opening shape from among a plurality of opening shapes stored in the opening shape storage unit,
The imaging apparatus according to claim 1, wherein the opening shape selection unit selects an opening shape based on selection of an opening shape by a user input to the operation input unit. An opening shape rotation unit that rotates the opening shape selected by the opening shape selection unit;
The operation input unit can also instruct rotation of the opening shape,
The imaging apparatus according to claim 2, wherein the opening shape rotating unit rotates the selected opening shape based on a rotation instruction by a user input to the operation input unit.   The imaging apparatus according to claim 2, further comprising an opening shape conversion unit that enlarges or reduces the opening shape selected by the opening shape selection unit. The operation input unit can also instruct to enlarge or reduce the opening shape,
The imaging apparatus according to claim 4, wherein the opening shape conversion unit enlarges or reduces the selected opening shape based on an enlargement or reduction instruction from the user input to the operation input unit. . A program shooting control unit that determines a shutter speed based on the aperture value when an aperture value is designated;
An aperture ratio calculation unit for obtaining an aperture ratio of the aperture shape from an aperture value;
Further comprising
The operation input unit can also indicate the aperture value,
The program photographing control unit determines a shutter speed based on an aperture value designated by the operation input unit,
The aperture ratio calculation unit obtains an aperture ratio of the aperture shape corresponding to the aperture value specified by the operation input unit,
The photographing according to claim 4, wherein the opening shape conversion unit enlarges or reduces the selected opening shape based on the opening ratio of the opening shape obtained by the opening ratio calculation unit. apparatus. A program shooting control unit that determines an aperture value based on the shutter speed when the shutter speed is designated;
An aperture ratio calculation unit for obtaining an aperture ratio of the aperture shape from an aperture value;
Further comprising
The operation input unit can also instruct the shutter speed,
The program photographing control unit determines an aperture value based on a shutter speed designated by the operation input unit,
The aperture ratio calculation unit obtains an aperture ratio of the aperture shape corresponding to the aperture value determined by the program shooting control unit,
The photographing according to claim 4, wherein the opening shape conversion unit enlarges or reduces the selected opening shape based on the opening ratio of the opening shape obtained by the opening ratio calculation unit. apparatus. A lens unit attached to the body of the photographing apparatus,
A lens unit comprising a pixel array aperture configured to drive the pixel array so as to transmit light in a region corresponding to the aperture shape, based on the indicated aperture shape. A computer program executed by a computer in the photographing apparatus,
The imaging apparatus includes an aperture shape storage unit for storing a plurality of aperture shapes, and a pixel array diaphragm configured by a pixel array,
The computer program is
An opening shape selection step of selecting one opening shape from a plurality of opening shapes stored in the opening shape storage unit;
A pixel array driving step of driving the pixel array of the pixel array diaphragm so as to transmit light in a region corresponding to the opening shape according to the opening shape selected in the opening shape selection step;
A computer program for causing the computer to execute.