JP3947689B2 - Electronic imaging device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an electronic imaging device, and in particular, an excellent abnormal state of a dustproof mechanism for an electronic imaging device such as a digital camera having an image sensor that obtains an image signal corresponding to light irradiated on its own photoelectric conversion surface. It relates to what can be detected.
[0002]
[Prior art]
In an electronic imaging device such as a digital camera, various mechanisms that are mechanically operated are arranged in the main body, so that dust or the like generated from the mechanism adheres to the photoelectric conversion surface of the imaging element and captures a captured image. There is a problem of deteriorating.
[0003]
Therefore, as an example of the technology related to the dust-proofing function of the electronic imaging device, the protective glass plate (also referred to as dust-proof glass or dust-proof filter) that protects the image sensor is vibrated to remove dust and the like adhering to the protective glass plate. The technique of dropping is proposed.
[0004]
For example, the applicant of this application has proposed such a technique by Japanese Patent Application No. 2000-401291.
[0005]
That is, in Japanese Patent Application No. 2000-401291, a piezoelectric element is provided as means for vibrating the protective glass plate, and the piezoelectric element is applied to the piezoelectric element by expanding and contracting in response to a periodic voltage applied. Techniques have been proposed in which the attached protective glass plate is vibrated at a predetermined cycle.
[0006]
[Problems to be solved by the invention]
By the way, in the technique proposed in Japanese Patent Application No. 2000-401291 as described above, since the amplitude of vibration of the dust-proof protective glass plate itself is slight, there is a problem in a part of the dust-proof mechanism. Even when sufficient vibration does not occur, it is expected that the situation cannot be confirmed with the naked eye.
[0007]
Therefore, a device such as a laser displacement meter is required to detect whether there is an abnormality in the dustproof mechanism.
[0008]
However, it is impossible for a general user to detect an abnormality of the dustproof mechanism with such a device, even if an abnormality occurs and a sufficient dustproof effect cannot be obtained. The fact is that it cannot be recognized.
[0009]
The present invention has been made in view of the above circumstances, and has a dust-proof mechanism in which dust or the like attached to the dust-proof filter is removed by vibrating a dust-proof filter provided on the front surface of the image sensor. It is an object of the present invention to provide an electronic imaging device that can easily detect a failure of a dustproof mechanism in the electronic imaging device.
[0010]
[Means for Solving the Problems]
  According to the present invention, in order to solve the above problems,
  (1)An electronic imaging device that performs a shooting operation using an imaging device,
  A dust filter disposed in front of the image sensor;
  A dust-proof mechanism for removing dust adhering to the surface of the dust-proof filter by vibrating the dust-proof filter with vibration means;
  Monitoring means for monitoring the vibration state of the dust filter;
  Drive means for supplying a drive signal having a predetermined frequency to the vibration means;
  By controlling the driving means, a resonance frequency detecting operation for detecting the resonance frequency of the dustproof filter and detecting an abnormality of the dustproof mechanism based on the output of the monitoring means, and the resonance frequency detecting operation is detected. Control means capable of performing a dust removal operation for driving the vibration means at a resonance frequency for a predetermined time and removing dust adhering to the surface of the dust filter by the dust prevention mechanism,
  When the electronic imaging device is activated, the control means performs the resonance frequency detection operation, and performs a dust removal operation when there is no abnormality in the dust prevention mechanism,
  An electronic image pickup apparatus that displays an error when the dust-proof mechanism is abnormal and prohibits execution of the dust removal operationIs provided.
[0011]
  Further, according to the present invention, in order to solve the above problems,
  (2)An electronic imaging device that performs a shooting operation using an interchangeable lens and an imaging device,
  A dust filter disposed in front of the image sensor;
  A dust-proof mechanism for removing dust adhering to the surface of the dust-proof filter by vibrating the dust-proof filter with vibration means;
  Monitoring means for monitoring the vibration state of the dust filter;
  Drive means for supplying a drive signal having a predetermined frequency to the vibration means;
  By controlling the driving means, a resonance frequency detecting operation for detecting the resonance frequency of the dustproof filter and detecting an abnormality of the dustproof mechanism based on the output of the monitoring means, and the resonance frequency detecting operation is detected. Control means capable of performing a dust removal operation for driving the vibration means at a resonance frequency for a predetermined time and removing dust adhering to the surface of the dust filter by the dust prevention mechanism,
  When the lens is replaced, the control means performs the resonance frequency detection operation, and performs a dust removal operation when there is no abnormality in the dustproof mechanism,
  An electronic image pickup apparatus that displays an error when the dust-proof mechanism is abnormal and prohibits execution of the dust removal operationIs provided.
[0012]
  Further, according to the present invention, in order to solve the above problems,
  (3)The drive means sequentially supplies a plurality of drive signals having different frequencies to the excitation means in the resonance frequency detection operation,
  The electronic imaging according to (1) or (2), wherein a resonance frequency of the dustproof filter and presence / absence of abnormality of the dustproof mechanism are detected based on an output signal from the monitor means for each driving signal. apparatusIs provided.
[0013]
  Further, according to the present invention, in order to solve the above problems,
  (4)The operation for detecting the presence / absence of abnormality of the dustproof mechanism is performed by determining whether or not the amplitude of the output signal from the monitor means for each of a plurality of drive signals having different frequencies is monotonously increasing. It is determined that there is an abnormality in the electronic imaging device according to (3)Is provided.
[0014]
  Further, according to the present invention, in order to solve the above problems,
  (5)The operation for detecting the presence or absence of abnormality of the dustproof mechanism is performed by determining whether or not the amplitude of the output signal from the monitor means for each of a plurality of drive signals having different frequencies is monotonously decreasing. It is determined that the dust-proof mechanism has an abnormality in the electronic imaging apparatus according to (3)Is provided.
[0015]
  Further, according to the present invention, in order to solve the above problems,
  (6)The operation for detecting the presence or absence of abnormality of the dustproof mechanism is performed by detecting an output signal having a maximum amplitude from output signals from the monitoring means for each of a plurality of drive signals having different frequencies, and the maximum value is predetermined. The electronic imaging device according to (3), wherein it is determined that there is an abnormality in the dustproof mechanism when it is not within the range ofIs provided.
[0016]
  Further, according to the present invention, in order to solve the above problems,
  (7)The operation for detecting the presence / absence of abnormality of the dustproof mechanism is performed by detecting an output signal having a maximum amplitude from output signals from the monitor means for each of a plurality of drive signals having different frequencies, and indicating the maximum value. The electronic imaging apparatus according to (3), wherein when the frequency value of the drive signal that outputs the output signal is not within a predetermined range, it is determined that the dustproof mechanism is abnormal.Is provided.
[0021]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings.
[0022]
FIG. 1 is a partially cutaway perspective view showing a schematic configuration of an embodiment when the present invention is applied to a digital camera.
[0023]
That is, FIG. 1 is a perspective view schematically showing an internal configuration of a part of the camera body cut away.
[0024]
The camera 1 according to the present embodiment includes a camera main body 11 and a lens barrel 12 that are separately configured. The camera main body 11 and the lens barrel 12 are configured to be detachable from each other. It will be.
[0025]
The lens barrel 12 is configured by holding therein a photographing optical system 12a composed of a plurality of lenses and their driving mechanisms.
[0026]
The photographing optical system 12a transmits a light beam from the subject so that an image of the subject formed by the subject light beam is formed at a predetermined position (on a photoelectric conversion surface of an image sensor described later). For example, it is composed of a plurality of optical lenses.
[0027]
The lens barrel 12 is disposed so as to protrude toward the front surface of the camera body 11.
[0028]
In addition, the camera body 11 includes various components and the like, and is a connecting member for disposing the lens barrel 12 holding the imaging optical system 12a so as to be detachable. This is a so-called single-lens reflex camera having an optical system mounting portion 11a provided on the front surface thereof.
[0029]
That is, an exposure opening having a predetermined aperture capable of guiding the subject light flux into the camera body 11 is formed at a substantially central part on the front side of the camera body 11, and the periphery of the exposure opening A photographing optical system mounting portion 11a is formed in the portion.
[0030]
On the outer surface side of the camera main body 11, the above-described photographing optical system mounting portion 11a is disposed on the front surface, and the camera main body 11 is operated to a predetermined position such as an upper surface or a back surface. For example, a release button 17 or the like for generating an instruction signal or the like for starting a photographing operation is provided.
[0031]
Inside the camera body 11, various components, for example, a finder device 13 that constitutes a so-called observation optical system, and a shutter mechanism that controls the irradiation time of the subject luminous flux on the photoelectric conversion surface of the image sensor, etc. The shutter unit 14 provided, an image pickup device (not shown) that obtains an image signal corresponding to the subject image, and a predetermined position on the front surface side of the photoelectric conversion surface of the image pickup device, dust or the like on the photoelectric conversion surface A plurality of circuits including an image pickup unit 15 including a dustproof filter (also referred to as dustproof glass) 21 which is a dustproof member for preventing adhesion of the liquid and a main circuit board 16 on which various electrical members constituting the electrical circuit are mounted. Substrates (only the main circuit board 16 is illustrated) are disposed at predetermined positions.
[0032]
The viewfinder device 13 receives a reflecting mirror 13b configured to bend the optical axis of a subject light beam transmitted through the photographing optical system 12a and guide the light beam to the observation optical system side, and a light beam emitted from the reflecting mirror 13b. A pentaprism 13a that forms an erect image and an eyepiece 13c that forms an image in an optimum form for magnifying and observing the image formed by the pentaprism 13a.
[0033]
The reflecting mirror 13b is configured to be movable between a position retracted from the optical axis of the photographing optical system 12a and a predetermined position on the optical axis. In a normal state, the reflecting mirror 13b is arranged on the optical axis of the photographing optical system 12a. They are arranged with a predetermined angle with respect to the optical axis, for example, an angle of 45 degrees.
[0034]
As a result, when the camera 1 is in the normal state, the subject luminous flux that has passed through the photographing optical system 12a is bent by the reflecting mirror 13b, and is reflected by the pentaprism 13a disposed above the reflecting mirror 13b. Reflected to the side.
[0035]
On the other hand, while the camera 1 is performing a photographing operation, the reflecting mirror 13b moves to a predetermined position retracted from the optical axis of the photographing optical system 12a. Guided to the side.
[0036]
The shutter unit 14 may be the same as that generally used in conventional cameras, such as a focal plane type shutter mechanism and its drive circuit.
[0037]
FIG. 2 is a block diagram showing the system configuration of the camera according to the first embodiment of the present invention.
[0038]
That is, the camera system according to the first embodiment is mainly composed of a camera body 11 and a lens barrel 12 as an interchangeable lens, and a desired lens barrel 12 with respect to the front surface of the camera body 11. Is set to be detachable.
[0039]
The lens barrel 12 is controlled by a lens control microcomputer (hereinafter referred to as “Lucom”) 205.
[0040]
The camera body 11 is controlled by a body control microcomputer (hereinafter referred to as Bucom) 150.
[0041]
Note that the Lucom 205 and Bucom 150 are electrically connected to each other via the communication connector 206 when they are combined.
[0042]
In this case, the Lucom 205 operates as a camera system in cooperation with the Bucom 150 in a dependent manner.
[0043]
In the lens barrel 12, a photographing optical system 12a and a diaphragm 203 are provided.
[0044]
The photographing optical system 12a is driven by a DC motor (not shown) in the lens driving mechanism 202.
[0045]
The diaphragm 203 is driven by a stepping motor (not shown) in the diaphragm drive mechanism 204.
[0046]
The Lucom 205 controls each of these motors according to a command from the Bucom 150.
[0047]
In the camera body 11, the following components are arranged as shown.
[0048]
For example, a single-lens reflex system component (penta prism 13a, reflecting mirror 13b, eyepiece 13c, sub mirror 114) as an optical system, a focal plane shutter 115 on the optical axis, and a reflected light beam from the sub mirror 14 And an AF sensor unit 116 for automatically measuring the distance.
[0049]
In addition, an AF sensor driving circuit 117 for driving and controlling the AF sensor unit 116, a mirror driving mechanism 118 for driving and controlling the reflecting mirror 13b, and a spring force for driving the front curtain and the rear curtain of the shutter 115 are charged. A shutter charge mechanism 119, a shutter control circuit 120 that controls the movement of the front curtain and the rear curtain, and a photometry circuit 121 that performs photometry based on the light flux from the pentaprism 13a.
[0050]
On the optical axis, an image sensor 27 for photoelectrically converting a subject image that has passed through the optical system is provided as a photoelectric converter.
[0051]
In this case, the image sensor 27 is protected by a dustproof filter 21 made of a transparent glass member as an optical element disposed between the image sensor 27 and the photographing optical system 12a.
[0052]
For example, a piezoelectric element 22 is attached to the peripheral portion of the dust filter 21 as a part of the vibration means that vibrates the dust filter 21 at a predetermined frequency.
[0053]
The piezoelectric element 22 has two electrodes. The piezoelectric element 22 vibrates the dust filter 21 by the dust filter driving circuit 140 as a part of the vibration means, and the dust adhered to the glass surface. It is comprised so that can be removed.
[0054]
Note that a temperature measurement circuit 133 is provided in the vicinity of the dust filter 21 in order to measure the temperature around the image sensor 27.
[0055]
The camera system also includes an image processing controller that performs image processing using an interface circuit 123 connected to the image sensor 27, a liquid crystal monitor 124, an SDRAM 125 provided as a storage area, a flash ROM 126, a recording medium 127, and the like. 128, and an electronic image display function as well as an electronic recording display function can be provided.
[0056]
As other storage areas, for example, a nonvolatile memory 129 made of an EEPROM is provided so as to be accessible from the Bucom 150 as nonvolatile storage means for storing predetermined control parameters necessary for camera control.
[0057]
In addition, the Bucom 150 is provided with an operation display LCD 151 and a camera operation switch (SW) 152 for notifying the user of the operation state of the camera by display output.
[0058]
The camera operation SW 152 is a switch group including operation buttons necessary for operating the camera, such as a release SW, a mode change SW, and a power SW.
[0059]
Furthermore, a battery 154 as a power source and a power circuit 153 that converts the voltage of the power source into a voltage required by each circuit unit constituting the camera system are provided.
[0060]
Next, the operation of the camera system configured as described above will be described. Each part of the camera system operates as follows.
[0061]
First, the image processing controller 128 captures image data from the image sensor 27 by controlling the interface circuit 123 in accordance with an instruction from the Bucom 150.
[0062]
This image data is converted into a video signal by the image processing controller 128 and output and displayed on the liquid crystal monitor 124.
[0063]
The user can confirm the captured image from the display image on the liquid crystal monitor 124.
[0064]
The SDRAM 125 is a memory for temporarily storing image data, and is used as a work area when image data is converted.
[0065]
The image data is set to be stored in the recording medium 127 after being converted into JPEG data.
[0066]
The image sensor 27 is protected by the dustproof filter 21 made of a transparent glass member as described above.
[0067]
A piezoelectric element 22 for oscillating the glass surface is disposed at the peripheral portion of the dust filter 21, and this piezoelectric element 22 can be used as a driving means for the piezoelectric element 22 as will be described in detail later. It is driven by a working dustproof filter driving circuit 140.
[0068]
It is more preferable for dust prevention that the image pickup element 27 and the piezoelectric element 22 are integrally housed in a case having the dust filter 21 as one surface and surrounded by a frame as shown by a broken line.
[0069]
Normally, temperature affects the elastic modulus of glass materials and is one of the factors that change its natural frequency. Therefore, the temperature must be measured during operation to take into account the change in natural frequency. Don't be.
[0070]
It is better to measure the temperature change of the dust-proof filter 21 provided to protect the front surface of the image sensor 27 where the temperature rises rapidly during operation, and to predict the natural frequency at that time.
[0071]
Therefore, in this example, a sensor (not shown) connected to the temperature measurement circuit 133 is provided to measure the ambient temperature of the image sensor 27.
[0072]
The temperature measurement point of the sensor is preferably set in the vicinity of the vibration surface of the dust filter 21.
[0073]
The mirror driving mechanism 118 is a mechanism for driving the reflecting mirror 13b to the UP position and the DOWN position. When the reflecting mirror 13b is at the DOWN position, the light beam from the photographing optical system 12a is pentagonal with the AF sensor unit 116 side. The light is divided and guided to the prism 13a side.
[0074]
The output from the AF sensor in the AF sensor unit 116 is transmitted to the Bucom 150 via the AF sensor driving circuit 117, and a known distance measurement process is performed.
[0075]
The eyepiece 13c adjacent to the pentaprism 13a allows the user to see the subject, while a part of the light beam that has passed through the pentaprism 13a is guided to a photosensor (not shown) in the photometry circuit 121, where it is detected. A well-known photometric process is performed based on the light quantity.
[0076]
Next, details of the imaging unit 15 in the camera 1 of the present embodiment will be described.
[0077]
3, 4, and 5 are views showing a part of the imaging unit 15 in the camera 1 of the present embodiment, and FIG. 3 is an exploded perspective view of a main part showing the imaging unit in an exploded manner. is there.
[0078]
4 is a perspective view showing a state in which the imaging unit is assembled in a cut state, and FIG. 5 is a cross-sectional view taken along the cut surface in FIG.
[0079]
Note that the imaging unit 15 of the camera 1 of the present embodiment is a unit configured by a plurality of members including the shutter unit 14 as described above, but the main part is illustrated in FIGS. 3 to 5. The illustration of the shutter portion 14 is omitted.
[0080]
3 to 5, in order to show the positional relationship between the constituent members, the image pickup device 27 is mounted in the vicinity of the image pickup unit 15, and includes an image signal processing circuit and a work memory. A main circuit board 16 on which an electric circuit of the imaging system is mounted is also illustrated.
[0081]
Note that the details of the main circuit board 16 itself are assumed to be those commonly used in conventional cameras and the like, and the description thereof will be omitted.
[0082]
The image pickup unit 15 is composed of a CCD or the like, and has an image pickup element 27 that obtains an image signal corresponding to the light that is transmitted through the shooting optical system 12a and irradiated on its own photoelectric conversion surface, and a thin plate-like member that fixes and supports the image pickup element 27. An image sensor fixing plate 28 made of a member and an optical element disposed on the photoelectric conversion surface side of the image sensor 27 and formed to remove a high frequency component from a subject luminous flux that is irradiated through the photographing optical system 12a. An optical low-pass filter (hereinafter referred to as an optical LPF) 25 and a low-pass filter receiving member which is disposed at a peripheral portion between the optical LPF 25 and the image sensor 27 and is formed by a substantially frame-shaped elastic member or the like. 26 and the image pickup device 27 are housed and fixedly held, and the optical LPF 25 (optical device) is closely attached to and supported by the peripheral portion or the vicinity thereof. An image sensor housing case member 24 (hereinafter referred to as a CCD case 24) disposed so as to be in close contact with a dustproof filter receiving member 23, which will be described later, at a predetermined portion, and disposed on the front side of the CCD case 24 A dust-proof filter receiving member 23 that supports the dust-proof filter 21 in close contact with the peripheral portion or the vicinity thereof, and a photoelectric conversion surface side of the image sensor 27 that is supported by the dust-proof filter receiving member 23 and on the front side of the optical LPF 25 On the side, a dustproof filter 21 that is a dustproof member disposed opposite to a predetermined position having a predetermined interval between the optical LPF 25, and a predetermined distance with respect to the dustproof filter 21 that is disposed on the periphery of the dustproof filter 21. A vibrating member for applying vibration, for example, a piezoelectric element 22 made of an electromechanical transducer or the like and a dustproof filter 21 are prevented. It is constituted by the pressing member 20 or the like made of an elastic body for fixing and holding is airtightly joined to the filter receiving member 23.
[0083]
The image sensor 27 receives an object light beam transmitted through the photographing optical system 12a on its own photoelectric conversion surface and performs a photoelectric conversion process to obtain an image signal corresponding to the object image formed on the photoelectric conversion surface. For example, a charge coupled device (CCD) is applied.
[0084]
The image sensor 27 is mounted at a predetermined position on the main circuit board 16 via the image sensor fixing plate 28.
[0085]
As described above, the image signal processing circuit, the work memory, and the like are mounted on the main circuit board 16, and signals output from the image sensor 27 are processed by these circuits.
[0086]
An optical LPF 25 is disposed on the front side of the image sensor 27 with a low-pass filter receiving member 26 interposed therebetween.
[0087]
A CCD case 24 is disposed so as to cover the image sensor 27, the low-pass filter receiving member 26, and the optical LPF 25.
[0088]
In other words, the CCD case 24 is provided with a rectangular opening 24c in a substantially central portion, and the optical LPF 25 and the image sensor 27 are disposed in the opening 24c from the rear side. .
[0089]
A step portion 24a having a substantially L-shaped cross section is formed on the inner peripheral edge portion on the rear side of the opening 24c as shown in FIGS.
[0090]
As described above, the low-pass filter receiving member 26 made of an elastic member or the like is disposed between the optical LPF 25 and the image sensor 27.
[0091]
The low-pass filter receiving member 26 is disposed at a position that avoids the effective range of the photoelectric conversion surface in the peripheral portion on the front surface side of the image sensor 27 and comes into contact with the vicinity of the peripheral portion on the back surface side of the optical LPF 25. Yes.
[0092]
In addition, substantially airtightness is maintained between the optical LPF 25 and the image sensor 27.
[0093]
Thereby, an elastic force in the optical axis direction by the low-pass filter receiving member 26 acts on the optical LPF 25.
[0094]
Therefore, a low-pass filter that displaces the optical LPF 25 in the optical axis direction by disposing the peripheral portion on the front side of the optical LPF 25 so as to be in substantially airtight contact with the stepped portion 24a of the CCD case 24. The position of the optical LPF 25 in the optical axis direction is regulated against the elastic force of the receiving member 26.
[0095]
In other words, the position of the optical LPF 25 inserted from the back side into the opening 24 c of the CCD case 24 is regulated in the optical axis direction by the step portion 24 a of the CCD case 24.
[0096]
Thus, the optical LPF 25 is prevented from coming out from the inside of the CCD case 24 toward the front side.
[0097]
Thus, after the optical LPF 25 is inserted into the opening 24c of the CCD case 24 from the back side, the image sensor 27 is disposed on the back side of the optical LPF 25.
[0098]
In this case, a low-pass filter receiving member 26 is sandwiched between the optical LPF 25 and the image sensor 27 at the periphery.
[0099]
Further, as described above, the image sensor 27 is mounted on the main circuit board 16 with the image sensor fixing plate 28 interposed therebetween.
[0100]
The imaging element fixing plate 28 is fixed to the screw hole 24e from the back side of the CCD case 24 with a screw 28b via a spacer 28a.
[0101]
Further, the main circuit board 16 is fixed to the image sensor fixing plate 28 with screws 16d through spacers 16c.
[0102]
On the front side of the CCD case 24, a dustproof filter receiving member 23 is fixed to the screw hole 24b of the CCD case 24 by screws 23b.
[0103]
In this case, a circumferential groove 24d is formed in a substantially annular shape at a predetermined position on the peripheral side of the CCD case 24 and on the front side as shown in detail in FIGS.
[0104]
On the other hand, an annular projection 23d (not shown in FIG. 3) corresponding to the circumferential groove 24d of the CCD case 24 is entirely provided at a predetermined position on the peripheral side of the dust-proof filter receiving member 23 and on the back side. It is formed in a substantially annular shape over the circumference.
[0105]
Therefore, the CCD case 24 and the dustproof filter receiving member 23 are fitted in the annular convex portion 23d and the circumferential groove 24d so that the annular region, that is, the region where the circumferential groove 24d and the annular convex portion 23d are formed. They are adapted to fit in a substantially airtight manner.
[0106]
The dust filter 21 has a circular or polygonal plate shape as a whole, and at least a region having a predetermined spread in the radial direction from its own center forms a transparent portion, and this transparent portion is a predetermined portion on the front side of the optical LPF 25. Are arranged opposite to each other with an interval of.
[0107]
Further, a peripheral portion of one surface of the dust filter 21 (the back side in this embodiment) is a predetermined vibration member for applying vibration to the dust filter 21 and is formed by an electromechanical conversion element or the like. For example, the piezoelectric elements 22 are arranged by means such as adhesion using an adhesive.
[0108]
The piezoelectric element 22 is configured such that a predetermined vibration can be generated in the dustproof filter 21 by applying a predetermined driving voltage from the outside.
[0109]
The dustproof filter 21 is fixed and held by a pressing member 20 made of an elastic body such as a leaf spring so as to be airtightly joined to the dustproof filter receiving member 23.
[0110]
In the vicinity of the substantially central portion of the dustproof filter receiving member 23, an opening 23f having a circular shape or a polygonal shape is provided.
[0111]
The opening 23f is set so that the subject light flux that has passed through the photographing optical system 12a passes and the light flux is sufficiently large to irradiate the photoelectric conversion surface of the image sensor 27 disposed behind the subject light flux. Yes.
[0112]
A wall portion 23e (see FIGS. 4 and 5) protruding to the front surface side is formed in a substantially annular shape at the peripheral edge of the opening 23f, and further toward the front surface side at the distal end side of the wall portion 23e. A receiving portion 23c is formed so as to protrude.
[0113]
On the other hand, in the vicinity of the outer peripheral edge portion on the front surface side of the dustproof filter receiving member 23, a plurality of (three in the present embodiment) protruding portions 23a are formed to protrude toward the front surface side at predetermined positions. .
[0114]
The protruding portion 23a is a portion formed to fix the pressing member 20 that fixes and holds the dustproof filter 21, and the pressing member 20 is a screw 20a or the like with respect to the distal end portion of the protruding portion 23a. It is fixed by the fastening means.
[0115]
As described above, the pressing member 20 is a member formed by an elastic body such as a leaf spring, the base end portion of which is fixed to the protruding portion 23a, and the free end portion of which is in contact with the outer peripheral edge portion of the dust filter 21. Thus, the dustproof filter 21 is pressed toward the dustproof filter receiving member 23, that is, in the optical axis direction.
[0116]
In this case, the positions of the dustproof filter 21 and the piezoelectric element 22 in the optical axis direction are brought into contact with the receiving portion 23c by a predetermined portion of the piezoelectric element 22 disposed on the outer peripheral edge of the dustproof filter 21 on the back side. Are now regulated.
[0117]
Therefore, the dustproof filter 21 is fixed and held so as to be airtightly joined to the dustproof filter receiving member 23 via the piezoelectric element 22.
[0118]
In other words, the dustproof filter receiving member 23 is configured to be airtightly bonded via the dustproof filter 21 and the piezoelectric element 22 by the urging force of the pressing member 20.
[0119]
Incidentally, as described above, the dustproof filter receiving member 23 and the CCD case 24 are configured such that the circumferential groove 24d and the annular convex portion 23d (see FIGS. 4 and 5) are fitted in a substantially airtight manner. At the same time, the dustproof filter receiving member 23 and the dustproof filter 21 are joined airtightly via the piezoelectric element 22 by the urging force of the pressing member 20.
[0120]
Further, the optical LPF 25 disposed in the CCD case 24 is disposed so as to be substantially airtight between the front peripheral side peripheral portion of the optical LPF 25 and the step portion 24 a of the CCD case 24.
[0121]
Furthermore, an image sensor 27 is disposed on the back side of the optical LPF 25 via a low-pass filter receiving member 26, so that substantially airtightness is maintained between the optical LPF 25 and the image sensor 27. ing.
[0122]
Accordingly, a predetermined gap 51a is formed in the space between the optical LPF 25 and the dustproof filter 21 as a result.
[0123]
A space 51 b is formed by the peripheral side of the optical LPF 25, that is, by the CCD case 24, the dustproof filter receiving member 23, and the dustproof filter 21.
[0124]
This space portion 51b is a sealed space formed so as to protrude outside the optical LPF 25 (see FIGS. 4 and 5).
[0125]
The space 51b is set so as to be a wider space than the gap 51a.
[0126]
The space formed by the gap 51a and the space 51b is a sealed space 51 that is sealed almost airtight by the CCD case 24, the dustproof filter receiving member 23, the dustproof filter 21, and the optical LPF 25 as described above. ing.
[0127]
As described above, in the imaging unit 15 in the camera of the present embodiment, the sealing structure portion that is formed on the periphery of the optical LPF 25 and the dustproof filter 21 and forms the substantially sealed space 51 including the gap 51a is configured. Yes.
[0128]
And this sealing structure part is provided in the outer position from the periphery of optical LPF25 thru | or its vicinity.
[0129]
Further, in the present embodiment, the dustproof filter receiving member 23 which is a first member that supports the dustproof filter 21 in close contact with the peripheral portion or the vicinity thereof, and the optical LPF 25 is closely attached to the peripheral portion or the vicinity thereof. The sealing structure portion is constituted by the CCD case 24, which is a second member disposed so as to be in close contact with the dustproof filter receiving member 23 at its own predetermined portion.
[0130]
In the camera of the present embodiment configured as described above, the dust filter 21 is disposed opposite to a predetermined position on the front surface side of the image sensor 27, and formed on the periphery of the photoelectric conversion surface of the image sensor 27 and the dust filter 21. The sealing space 51 to be sealed is configured to prevent dust and the like from adhering to the photoelectric conversion surface of the image sensor 27.
[0131]
In this case, with respect to dust adhering to the exposed surface on the front side of the dustproof filter 21, a periodic voltage is applied to the piezoelectric element 22 disposed so as to be integrated with the peripheral portion of the dustproof filter 21. The dust filter 21 can be removed by applying a predetermined vibration.
[0132]
FIG. 6 is a front view showing only the dust filter 21 and the piezoelectric element 22 provided integrally therewith in the imaging unit 15 of the camera 1.
[0133]
7 and 8 show changes in the state of the dustproof filter 21 and the piezoelectric element 22 when a driving voltage is applied to the piezoelectric element 22 in FIG. 6, and FIG. 7 is along the line AA in FIG. FIG. 8 is a sectional view taken along line BB in FIG.
[0134]
Here, for example, when a negative (minus; one) voltage is applied to the piezoelectric element 22, the dustproof filter 21 is deformed as indicated by the solid line in FIGS. 7 and 8, while the piezoelectric element 22 is positive (plus). ;) When a voltage is applied, the dustproof filter 21 is deformed as indicated by a dotted line in FIG.
[0135]
In this case, since the amplitude is substantially zero at the position of the vibration node as indicated by reference numeral 21a in FIGS. 6 to 8, the receiving portion of the dustproof filter receiving member 23 is located at a portion corresponding to this node 21a. 23c is set to contact.
[0136]
Thereby, the dustproof filter 21 can be efficiently supported without inhibiting the vibration of the dustproof filter 21.
[0137]
In this state, the dustproof filter driving unit 48 is controlled at a predetermined time and a periodic voltage is applied to the piezoelectric element 22, so that the dustproof filter 21 vibrates and the surface of the dustproof filter 21 is vibrated. Adhered dust and the like are removed.
[0138]
Note that the resonance frequency at this time is determined by the shape, plate thickness, material, and the like of the dust filter 21.
[0139]
In the example shown in FIGS. 6 to 8 described above, the case where the primary vibration is generated is shown. However, the present invention is not limited to this, and higher-order vibration may be generated.
[0140]
Next, based on the circuit diagram of the dustproof filter driving circuit 140 shown in FIG. 9 and the time chart of FIG. 10, the driving of the dustproof filter 21 of the camera with the dustproof function in the first embodiment and the operation and control thereof. explain.
[0141]
The dust filter driving circuit 140 illustrated here has a circuit configuration as shown in FIG. 9, and in each part, waveform signals (Sig1 to Sig6) represented by the time chart of FIG. 10 are generated, and based on those signals. And is controlled as follows.
[0142]
That is, as illustrated in FIG. 9, the dustproof filter drive circuit 140 includes an N-ary counter 41, a 1/2 frequency divider circuit 42, an inverter 43, and a plurality of MOS transistors (Q00, Q01, Q02) 44a, 44b, 44c, Transformer 45, resistor (R00) 46, A / D converter 60, first electrode A of piezoelectric element 22 and second electrode B61 aligned therewith, diode (D00) 62, resistors (R01, R02) 63, 64, And a capacitor (C00) 65.
[0143]
A signal (Sig4) having a predetermined cycle is generated on the secondary side of the transformer 45 by the ON / OFF switching operation of the transistor (Q01) 44b and the transistor (Q02) 44c connected to the primary side of the transformer 45. Based on the signal of this predetermined cycle, the piezoelectric element 22 having the two electrodes A and B is driven in various forms, and an effective resonance frequency is found to effectively resonate the dustproof filter 21. (Details will be described later).
[0144]
The Bucom 150 has two IO ports P provided as control ports. PwCont and IO port D The dust filter driving circuit 140 is controlled as follows through NCnt and the clock generator 55 existing inside the Bucom 150.
[0145]
The clock generator 55 outputs a pulse signal (basic clock signal) having a frequency sufficiently higher than the signal frequency applied to the piezoelectric element 22 to the N-ary counter 41.
[0146]
The output signal from the clock generator 55 is a signal Sig1 having a waveform shown in the time chart of FIG.
[0147]
The basic clock signal from the clock generator 55 is input to the N-ary counter 41.
[0148]
The N-ary counter 41 counts the pulse signal and outputs a count end pulse signal every time it reaches a predetermined value “N”.
[0149]
That is, the N-ary counter 41 divides the basic clock signal from the clock generator 55 by 1 / N.
[0150]
The output signal from the N-ary counter 41 is a signal Sig2 having a waveform shown in the time chart of FIG.
[0151]
The pulse signal divided by the N-ary counter 41 does not have a high and low duty ratio of 1: 1.
[0152]
Therefore, the pulse signal divided by the N-ary counter 41 is converted into a duty ratio of 1: 1 through the 1/2 divider circuit 42.
[0153]
Note that the pulse signal converted by the ½ divider circuit 42 corresponds to the signal Sig3 having the waveform shown in the time chart of FIG.
[0154]
In the High state of the pulse signal converted by the 1/2 frequency divider circuit 42, the MOS transistor (Q01) 44b to which this signal is input is turned on.
[0155]
On the other hand, this pulse signal is applied to the transistor (Q02) 44c via the inverter 43.
[0156]
Therefore, in the low state of the pulse signal converted by the 1/2 frequency divider circuit 42, the transistor (Q02) 4c to which this signal is input is turned on.
[0157]
When the transistor (Q01) 44b and the transistor (Q02) 44c connected to the primary side of the transformer 45 are turned ON alternately, a signal Sig4 having a waveform represented by (d) i in FIG. A signal having a period as shown below is generated.
[0158]
The winding ratio of the transformer 45 is determined from the output voltage of the power supply circuit unit 153 and the voltage necessary for driving the piezoelectric element 22.
[0159]
The resistor (R00) 46 is provided to restrict an excessive current from flowing through the transformer 45.
[0160]
When driving the piezoelectric element 22, the transistor (Q00) 44 a is in an ON state, and a voltage must be applied from the power supply circuit unit 153 to the center tap of the transformer 45.
[0161]
In FIG. 9, ON / OFF control of the transistor (Q00) 44a is performed via P_PwCont of the IO port.
[0162]
The set value “N” of the N-ary counter 41 can be set from the IO port D_NCnt.
[0163]
That is, the Bucom 150 can arbitrarily change the drive frequency of the piezoelectric element 22 by appropriately controlling the set value “N” of the N-ary counter 41.
[0164]
At this time, the driving frequency of the piezoelectric element 22 can be calculated by the following equation (1).
[0165]
fdrv = fpls / 2N (1)
Where N is the set value for the counter, fpls is the frequency of the output pulse of the clock generator,
fdrv: frequency of a signal applied to the piezoelectric element.
[0166]
The calculation based on this equation is performed by the CPU (control means) of the Bucom 150.
[0167]
The electrode B61 of the piezoelectric element 22 described above is an electrode for detecting the vibration state of the glass plate.
[0168]
An alternating voltage (monitor signal) corresponding to the vibration state of the glass plate is generated from the electrode B61.
[0169]
This monitor signal is Sig5 having a waveform shown in the time chart of FIG.
[0170]
A diode (D00) 62 connected to the electrode B61 of the piezoelectric element 22 is provided for half-wave rectification of the monitor signal.
[0171]
An envelope of the monitor signal is formed by the resistors (R01, R02) 63 and 64 and the capacitor (C00) 65 following the diode (D00) 62.
[0172]
The optimal value of the time constant determined by the detection circuit including the resistors (R01, R02) 63 and 64 and the capacitor (C00) 65 varies depending on the vibration frequency of the glass.
[0173]
The monitor signal is reduced to a level that can be input to the A / D converter 60 by the resistors (R01, R02) 63, 64.
[0174]
This decompressed monitor signal is Sig6 having a waveform shown in the time chart of FIG.
[0175]
The decompressed monitor signal is converted into digital data by the A / D converter 60 and read from the IO port D_ADCin of the Bucom 150.
[0176]
The Bucom 150 may determine a value to be set in the N-ary counter 41 so that the monitor signal becomes the maximum level.
[0177]
When driving the glass of the piezoelectric element 22 with the value (resonance frequency) of the N-ary counter 41 indicating the maximum level, dust can be efficiently removed.
[0178]
Next, the control performed by the above-described camera body control microcomputer (BUcom) 150 will be specifically described with reference to FIG.
[0179]
FIG. 11 is a flowchart illustrating a main routine of a control program that operates on the Bucom 150.
[0180]
First, when the power SW (not shown) of the camera is turned on, the Bucpm 150 starts operation, and in step # 000, processing for starting the camera system is executed.
[0181]
That is, in step # 000, the power supply circuit 153 is controlled to supply power to each circuit unit constituting this camera system, and initial setting of each circuit is performed.
[0182]
Next, in step # 001, the subroutine “resonance point detection operation” is called and executed.
[0183]
In this subroutine “resonance point detection operation”, a driving frequency (resonance frequency) suitable for efficiently vibrating the dustproof filter 21 is detected (details will be described later).
[0184]
This frequency data is stored in a memory area of a predetermined address of Bucom 150.
[0185]
Next, in step # 002, the subroutine “dust removal operation” is called and executed.
[0186]
During this subroutine “dust removal operation”, the camera is used for photographing by vibrating the dust filter 21 at the resonance frequency detected in step # 001 and shaking off the dust adhering to the glass surface of the piezoelectric element 22. It is possible to remove dust unintentionally attached by the user during the period when the user does not.
[0187]
The next step # 003 is a step that is periodically executed, and is an operation step for detecting the state of the lens barrel 12 when the Bucom 150 performs a communication operation with the Lucom 205.
[0188]
If it is detected in step # 004 that the lens barrel 12 is attached to the camera body 11, the process proceeds to step # 007.
[0189]
On the other hand, when it is detected that the lens barrel 12 has been removed from the camera body 11, the process proceeds from step # 005 to step # 006, the control flag FLens is reset, and then the process proceeds to step # 010.
[0190]
Next, if it is not detected in step # 004 that the lens barrel 12 is attached to the camera body 11, a control flag F_Lens is set in step # 007.
[0191]
The control flag F_Lens indicates “1” when the lens barrel 12 is attached to the camera body 11 and indicates “0” when the lens barrel 12 is removed.
[0192]
In step # 008, the subroutine “resonance point detection operation” is called and executed in the same manner as described above, and in step # 009 immediately after that, in the same manner as described above, the subroutine “for removing dust from the dust filter 21” is displayed. "Dust removal operation" is called and executed.
[0193]
Usually, there is a high possibility that dust adheres to the dustproof filter 21 and the like during a period when the lens barrel 12 is not attached to the camera body 11 which is the camera body.
[0194]
Therefore, it is desirable to perform the dusting operation at the timing when the mounting of the lens barrel 12 is detected.
[0195]
When the lens is exchanged, the outside air circulates inside the camera and the temperature inside the camera changes, and the resonance frequency of the glass of the piezoelectric element 22 also changes due to this temperature change.
[0196]
Therefore, in step # 008, the subroutine "resonance point detection operation" is executed in order to determine a new drive frequency (resonance frequency).
[0197]
Subsequently, in step # 009 immediately after that, the subroutine “dust removal operation” is executed at the frequency determined in step # 008.
[0198]
Next, in step # 010, the state of the camera operation SW 152 is detected, and when a state change of a CleanUP-SW (not shown) which is one of the camera operation SW 152 is detected in the next step # 110, step # 012 is detected. Migrate to
[0199]
Next, after an operation for detecting the resonance point is executed in step # 012, an operation for removing dust from the dustproof filter 21 is executed in step # 013.
[0200]
In this case, in conjunction with the operation of step # 012, in step # 013, the operation of taking in pixel defect information of the CCD (imaging device) is executed.
[0201]
This defective pixel information is stored in the FlashRom 126 and used for correcting the image data. However, if dust is attached, accurate defect information cannot be obtained.
[0202]
Therefore, before the operation of step # 0131, a series of operations of step # 012 and step # 013 are executed in the same manner as described above.
[0203]
Next, in step # 014, 1st. It is determined whether a release SW (not shown) has been operated.
[0204]
If 1st. If the release SW is on, the process proceeds to step # 015. If the release SW is off, the process proceeds to step # 003.
[0205]
Next, in step # 015, when the luminance information of the subject is obtained from the photometry circuit 121, the exposure time (Tv value) of the image sensor 27 and the aperture setting value (AV value) of the photographing lens 1 are calculated from the luminance information.
[0206]
Next, in step # 016, when the detection data of the AF sensor unit 116 is obtained via the AF sensor drive circuit 117, the amount of focus shift is calculated based on this detection data.
[0207]
Here, at step # 017, the control flag F The lens state is determined, and if it is “0”, it means that the lens barrel 12 does not exist. Therefore, the photographing operation after the next step # 018 cannot be executed. Shift to # 003 again.
[0208]
Next, in step # 018, a focus shift amount is transmitted to the Lucom 205, and a command to drive the photographing optical system 12a based on the shift amount is given.
[0209]
Next, at step # 019, 2nd. It is determined whether a release SW (not shown) has been operated.
[0210]
Here, the 2nd. When the release SW is ON, the process proceeds to step # 0190 to perform a predetermined photographing operation. When the release SW is OFF, the process proceeds to #step 003 again.
[0211]
In the next step # 0190, a “dust removal operation” routine is executed to remove dust prior to the photographing operation.
[0212]
However, the “resonance point detection operation” routine is not executed here in order to avoid the occurrence of a time lag due to the execution of the dust removal operation.
[0213]
In order to reliably remove dust, it is desirable to perform the operations of these two routines together. However, if there is no possibility that the resonance frequency will change, the “resonance point detection operation” routine may be omitted. Absent.
[0214]
However, this does not apply when the camera system is powered on, when the lens is replaced, or when a pixel defect detection operation of the CCD (imaging device) is performed.
[0215]
In the next step # 020, first, the Av value is transmitted to the Lucom 205, the driving of the diaphragm 203 is instructed, and the reflecting mirror (mirror) 13b is moved to the UP position in step # 021.
[0216]
Next, in step # 022, the front curtain travel of the shutter 14 is started, and then in step # 023, the image processing controller 128 is instructed to perform an imaging operation.
[0217]
When the exposure to the image sensor 27 is completed for the time indicated by the Tv value, the rear curtain travel of the shutter 14 is started in Step # 024, and then the reflecting mirror 13b is driven to the Down position in Step # 025. In parallel with this, the shutter 14 is charged.
[0218]
In step # 026, Lucom 205 is instructed to return the aperture 203 to the open position, and in step # 027, the image processing controller 128 is recorded with the captured image data on the recording medium 127. When the command is issued and the recording of the image data ends, the process proceeds to step # 003 again.
[0219]
Next, the details of the subroutine “dust removal operation” will be described with reference to the flowchart shown in FIG.
[0220]
In this subroutine “dust removal operation”, the piezoelectric element 22 is driven so that the dustproof filter 21 is resonated.
[0221]
First, as will be described later in Step # 200, it is determined whether or not an operation prohibition flag is set in the EEPROM 129.
[0222]
This operation prohibition flag is set when a proper resonance point is not detected in the resonance point detection operation of step # 001 of FIG. 11 described above, that is, when it is determined that there is some abnormality in the dustproof mechanism ( Details will be described later).
[0223]
If this operation prohibition flag is set, the dustproof operation is not executed, and the routine returns directly to the main routine.
[0224]
However, if the operation prohibition flag is not set, a preparatory operation for driving the piezoelectric element 22 is performed in step # 201.
[0225]
This is the IO port P This is an operation of controlling the PwCont to turn on the transistor Q00 and starting the output of the pulse signal from the clock generator 55.
[0226]
Next, in step # 202, a preset value (N) relating to the resonance frequency of the dustproof filter 21 detected by the resonance point detection operation in step # 001 of FIG. 11 is read.
[0227]
By setting the read value to the N-ary counter 41, the dustproof filter driving circuit 140 drives the dustproof filter 21 at its resonance frequency.
[0228]
Next, in step # 203, data corresponding to 100 mS is set in the timer counter 1, and the count operation is started.
[0229]
Next, in step # 204, it waits until the count operation of the timer counter 1 is completed.
[0230]
In step # 205, a process for stopping the driving operation is performed to turn off the transistor Q00, stop the operation of the clock generator 55, and then return to the main routine.
[0231]
Next, the details of the subroutine “resonance point detection operation will be described with reference to the flowchart shown in FIG.
[0232]
Usually, the resonance frequency of the dustproof filter 21 varies depending on the shape, material, support method, and vibration mode (vibration form) of the glass plate.
[0233]
In addition, when mass-produced as protective glass, the resonance frequency varies due to variations in processing accuracy.
[0234]
Therefore, if the resonance frequency of each dustproof filter 21 is measured and the frequency of the oscillator that applies a voltage to the piezoelectric element 22 is appropriately adjusted during operation, the variation can be offset.
[0235]
In this subroutine, an operation for detecting a resonance frequency (resonance point) when performing the dustproof operation is executed.
[0236]
Further, in this subroutine “resonance point detection operation”, it is also possible to detect an abnormal state of the dustproof mechanism including the dustproof filter 21.
[0237]
First, in step # 101, while sequentially changing the drive frequency of the piezoelectric element 22, the preset value set in the N-ary counter 41 is a predetermined time from the minimum value 493 to the maximum value 507 shown as a table format in FIG. While changing each one, the monitor signal (Sig6 on the time chart of FIG. 10F) at each drive frequency is detected by the A / D converter 60, and the data is sequentially stored in a predetermined memory area.
[0238]
For convenience, the driving frequency 40.57 Hz corresponding to the minimum preset value 493 shown as a table format in FIG. 18 is referred to as F1, and the driving frequency 39.45 Hz corresponding to the maximum preset value 507 is referred to as F2.
[0239]
Next, in step # 102, the maximum value of the monitor signal data stored in the predetermined memory area is detected.
[0240]
In general, when there is no problem with the dustproof mechanism, the monitor signal should peak near the resonance frequency of the dustproof filter 21, but when there is an abnormality somewhere in the dustproof mechanism, the drive frequency is set. Even if the shift is sequentially performed from F1 to F2, a peak may not be found in the meantime.
[0241]
For example, in a graph with the driving frequency on the horizontal axis and the level of the monitor output signal on the vertical axis, the case of a monotonically increasing pattern as shown in FIG. 14 or the case of a monotonic decreasing pattern as shown in FIG. Equivalent to.
[0242]
Therefore, when the level of the monitor output signal at each drive frequency is compared in step # 102, and the monotonically increasing tendency or the monotonically decreasing tendency is shown as a whole, the dustproof mechanism is abnormal. Judgment can be made.
[0243]
Next, in step # 103, it is determined whether or not the level of the monitor output signal is monotonically increasing. If monotonically increasing, the process proceeds to an abnormality process after step # 109.
[0244]
In step # 104, it is determined whether or not the level of the monitor output signal is monotonously decreased. If the level is monotonously decreased, the process proceeds to an abnormality process after step # 109 as described above.
[0245]
When the monitor output signal level is not monotonously increasing or decreasing, that is, when the peak (resonance point) of the monitor output signal is between the frequencies F1 and F2, the process proceeds to step # 105 and the monitor output signal level is increased. Determine the level.
[0246]
When the monitor output signal level is not within the predetermined range, it is considered that the dustproof mechanism is abnormal.
[0247]
Taking the three curves a, b, and c shown in FIG. 16 as an example, since the maximum values (peak values) of a and c are not in the range of Mmin to Mmax, it is determined that some abnormality has occurred in the dustproof mechanism. can do.
[0248]
Therefore, if it is determined in step # 105 that the maximum value of the monitor signal output is less than Mmin, the process proceeds to the abnormality process after # 109.
[0249]
Also, when it is determined in step # 106 that the maximum value of the monitor signal output is larger than Mmax, the process proceeds to the abnormality process after step # 109 as described above.
[0250]
If it is determined in step # 105 or step # 106 that the level of the monitor output signal is within a predetermined range, the process proceeds to step # 107, and the drive frequency at which the monitor output signal shows the maximum value is set to the resonance frequency F. Set to be.
[0251]
Note that even if there is a maximum value between the drive frequencies F1 and F2, if the value deviates significantly from the design value, some abnormality has occurred in the dustproof mechanism, and correct vibration is applied. There is a possibility that it cannot be done.
[0252]
Therefore, in order to eliminate such a risk, further verification of the resonance frequency F is performed in step # 108.
[0253]
Taking the two curves e and f shown in FIG. 17 as an example, the curve of e shows normal characteristics, but the curve of f is expected to have some abnormality because the peak position is extremely biased to F1. it can.
[0254]
Accordingly, in step # 108, if the frequency (resonance frequency) of the peak position is not within the predetermined range (Fref1 to Fref2), it is determined that the dustproof mechanism is abnormal, and the process proceeds to an abnormality process after step # 109. I am trying.
[0255]
Note that the above-described monitor output signal determination ranges Mmin to Mmax and resonance frequency determination ranges Fref1 to Fref2 are values calculated at the time of design according to the shape, material, support method, vibration mode, and the like of the dust filter 21.
[0256]
If no abnormality is found, the resonance frequency F is set and the process returns to the main routine. If any abnormality is found, a warning is given to the user in step # 109. An error is displayed using a sounding member (not shown) or LED.
[0257]
Thereafter, in step # 110, an operation prohibition flag for prohibiting the subsequent dustproof operation is written and set in the EEPROM 129, and the process returns to the main routine.
[0258]
When the operation prohibition flag is written in the EEPROM 129, the dustproof operation is not performed unless repair is performed at a service center or the like thereafter.
[0259]
By doing so, it is possible to prevent an accident that drives the dustproof mechanism in an abnormal state and destroys not only the dustproof mechanism but also the camera itself.
[0260]
【The invention's effect】
Therefore, as described above, according to the present invention, an electronic device having a dust-proof mechanism that causes dust or the like attached to the dust-proof filter to be removed by vibrating the dust-proof filter provided on the front surface of the image sensor. In the imaging apparatus, it is possible to provide an electronic imaging apparatus that can easily detect abnormality of the dustproof mechanism.
[Brief description of the drawings]
FIG. 1 is a partially cutaway perspective view showing a schematic configuration of an embodiment when the present invention is applied to a digital camera.
FIG. 2 is a block diagram showing a system configuration of a camera according to an embodiment of the present invention.
FIG. 3 is a view showing a part of the image pickup unit 15 in the camera 1 according to the embodiment of the present invention, and is an exploded perspective view of the main part showing the image pickup unit disassembled.
FIG. 4 is a view showing a part of the imaging unit 15 in the camera 1 according to the embodiment of the present invention, and is a perspective view showing a part of the assembled state of the imaging unit. .
5 is a view showing a part of the imaging unit 15 in the camera 1 according to the embodiment of the present invention, and is a cross-sectional view taken along the cut surface of FIG.
FIG. 6 is a front view showing only the dust filter 21 and the piezoelectric element 22 provided integrally therewith in the imaging unit 15 in the camera 1 according to the embodiment of the present invention.
7 is a cross-sectional view taken along line AA in FIG. 6 to show changes in the state of the dustproof filter 21 and the piezoelectric element 22 when a drive voltage is applied to the piezoelectric element 22 in FIG. It is.
8 is a cross-sectional view taken along line BB in FIG. 6 to show changes in the state of the dustproof filter 21 and the piezoelectric element 22 when a driving voltage is applied to the piezoelectric element 22 in FIG. 6; It is.
FIG. 9 is a circuit diagram of a dustproof filter driving circuit 140 in the camera 1 according to the embodiment of the present invention.
FIG. 10 is a time chart shown for explaining the driving of the dustproof filter 21 of the camera with the dustproof function according to the embodiment of the present invention and the operation and control thereof.
FIG. 11 is a flowchart illustrating a main routine of a control program operating on the Bucom 150 in the camera 1 according to the embodiment of the present invention.
FIG. 12 is a flowchart for explaining a subroutine “dust removal operation” of FIG. 11;
FIG. 13 is a flowchart shown for explaining the subroutine “resonance point detection operation” of FIG. 11;
FIG. 14 is a diagram illustrating a case where the camera 1 according to the embodiment of the present invention has a monotonically increasing pattern in a graph in which the horizontal axis represents the drive frequency and the vertical axis represents the level of the monitor output signal.
FIG. 14 is a diagram illustrating a case in which a reduction pattern is obtained in a graph in which the horizontal axis represents the drive frequency and the vertical axis represents the level of the monitor output signal in the camera 1 according to the embodiment of the present invention.
FIG. 16 is a case where it can be determined that some abnormality has occurred in the dustproof mechanism when the monitor output signal level is not within the predetermined range in the camera 1 according to the embodiment of the present invention. FIG.
FIG. 17 is a diagram illustrating a verification performed to obviate a possibility that a certain vibration has occurred in the dust-proof mechanism in the camera 1 according to the embodiment of the present invention, and there is a possibility that correct vibration cannot be applied. It is a figure illustrated.
FIG. 18 is a diagram showing preset values set in an N-ary counter 41 in the camera 1 according to the embodiment of the present invention as a table format.
[Explanation of symbols]
1 ... Camera,
11 ... camera body,
11a: photographing optical system mounting part,
12 ... Lens barrel,
12a: photographing optical system,
13 ... Finder device,
13a ... penta prism,
13b ... Reflector,
13c ... eyepiece,
14 ... shutter part,
15 ... Imaging unit,
16 ... main circuit board,
16c: spacer,
16d ... screw,
17 ... Release button,
21 ... Dustproof filter (dustproof glass),
150 ... Body control microcomputer (Bucom),
205 ... Lens control microcomputer (Lucom),
206 ... Connector,
202 ... Lens drive mechanism,
203 ... Aperture,
204: Aperture drive mechanism,
114 ... Submirror,
115 ... shutter,
116: AF sensor unit,
117... AF sensor driving circuit,
118 ... Mirror drive mechanism,
119 ... Shutter charge mechanism,
120. Shutter control circuit,
121: Photometric circuit,
27. Image sensor,
22: Piezoelectric element,
140 ... Dustproof filter drive circuit,
133 ... temperature measuring circuit,
123 ... interface circuit,
124 ... LCD monitor,
125 ... SDRAM,
126 ... FlashROM,
127 ... recording media,
128: Image processing controller,
129: Non-volatile memory (EEPROM),
151... LCD for operation display,
152 ... Camera operation switch (SW),
154 ... Battery as a power source,
153 ... power supply circuit,
20 ... Pressing member,
20a ... screw,
28 ... Image sensor fixing plate,
28a ... spacer,
28b ... screw,
25: Optical low-pass filter (optical LPF),
26: Low-pass filter receiving member,
23 ... Dustproof filter receiving member,
23a ... projection,
23b ... screws,
23c ... receiving part,
23d ... annular projection,
23e ... wall,
23f ... opening,
24 ... Imaging element storage case member (CCD case),
24a ... a step,
24b ... screw hole, 24c ... opening,
24e ... screw holes,
24d ... circumferential groove,
20 ... Pressing member,
51a ... gap,
51b ... space part,
51. Sealing space,
21a ... node of vibration,
48 ... Dustproof filter drive unit,
41 ... N-ary counter,
42 ... 1/2 frequency divider,
43. Inverter,
44a, 44b, 44c ... MOS transistors (Q00, Q01, Q02),
45 ... Trans,
46: Resistance (R00),
60 ... A / D converter,
61 ... the second electrode (B) of the piezoelectric element 22,
62 ... Diode (D00),
63, 64 ... resistors (R01, R02),
65: Capacitor (C00)

Claims (7)

An electronic imaging device that performs a shooting operation using an imaging device,
A dust filter disposed in front of the image sensor;
A dust-proof mechanism for removing dust adhering to the surface of the dust-proof filter by vibrating the dust-proof filter with a vibrating means;
Monitoring means for monitoring the vibration state of the dust filter;
Drive means for supplying a drive signal having a predetermined frequency to the vibration means;
By controlling the driving means, a resonance frequency detecting operation for detecting the resonance frequency of the dustproof filter and detecting an abnormality of the dustproof mechanism based on the output of the monitoring means, and the resonance frequency detecting operation is detected. Control means capable of performing a dust removal operation for driving the vibration means at a resonance frequency for a predetermined time and removing dust adhering to the surface of the dust filter by the dust prevention mechanism,
When the electronic imaging device is activated, the control unit performs the resonance frequency detection operation, and performs a dust removal operation when there is no abnormality in the dust prevention mechanism,
An electronic imaging apparatus characterized by displaying an error when the dustproof mechanism is abnormal and prohibiting execution of the dust removal operation. An electronic imaging device that performs a shooting operation using an interchangeable lens and an imaging device,
A dust filter disposed in front of the image sensor;
A dust-proof mechanism for removing dust adhering to the surface of the dust-proof filter by vibrating the dust-proof filter with a vibrating means;
Monitoring means for monitoring the vibration state of the dust filter;
Drive means for supplying a drive signal having a predetermined frequency to the vibration means;
By controlling the driving means, a resonance frequency detecting operation for detecting the resonance frequency of the dustproof filter and detecting an abnormality of the dustproof mechanism based on the output of the monitoring means, and the resonance frequency detecting operation is detected. Control means capable of performing a dust removal operation for driving the vibration means at a resonance frequency for a predetermined time and removing dust adhering to the surface of the dust filter by the dust prevention mechanism,
When the lens is replaced, the control means performs the resonance frequency detection operation, and performs a dust removal operation when there is no abnormality in the dustproof mechanism,
An electronic imaging apparatus characterized by displaying an error when the dustproof mechanism is abnormal and prohibiting execution of the dust removal operation. The drive means sequentially supplies a plurality of drive signals having different frequencies to the excitation means in the resonance frequency detection operation,
3. The electronic image pickup apparatus according to claim 1, wherein a resonance frequency of the dustproof filter and presence / absence of abnormality of the dustproof mechanism are detected based on an output signal from the monitor means for each driving signal. The operation for detecting the presence / absence of abnormality of the dustproof mechanism is performed by determining whether or not the amplitude of the output signal from the monitor means for each of a plurality of drive signals having different frequencies is monotonously increasing. The electronic imaging apparatus according to claim 3, wherein the electronic imaging device is determined to have an abnormality. The operation for detecting the presence or absence of abnormality of the dustproof mechanism is performed by determining whether or not the amplitude of the output signal from the monitor means for each of a plurality of drive signals having different frequencies is monotonously decreasing. The electronic imaging apparatus according to claim 3, wherein it is determined that the dustproof mechanism has an abnormality. The operation for detecting the presence or absence of abnormality in the dustproof mechanism is performed for each of a plurality of drive signals having different frequencies. An output signal having a maximum amplitude is detected from the output signals from the monitoring means, and when the maximum value is not within a predetermined range, it is determined that there is an abnormality in the dustproof mechanism. The electronic imaging device according to claim 3. The operation for detecting the presence / absence of abnormality of the dustproof mechanism is performed by detecting an output signal having a maximum amplitude from output signals from the monitoring means for each of a plurality of drive signals having different frequencies, and indicating the maximum value. The electronic imaging apparatus according to claim 3, wherein when the frequency value of the drive signal that outputs the output signal is not within a predetermined range, it is determined that the dustproof mechanism is abnormal.

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