JP2004112600A - Shooting control system - Google Patents

Abstract

Provided is a photographing control system having a function of easily or intentionally photographing a quaint or playful image having low image quality or a defect.
An appropriate value for an automatic mechanism of AF, AE, blur correction, and AWB is shifted by a predetermined amount in a shooting condition, or a defect phenomenon such as multiple exposure, frame overlap, and light leakage is intentionally caused to reduce a low value. A tasteful or playful image having an image quality or a defect is obtained.
[Selection diagram] Fig. 1

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a shooting control system in a silver halide film camera, digital camera, movie camera, and the like.
[0002]
[Prior art]
Conventionally, all silver halide film cameras and digital cameras have technically advanced to obtain better photographing results (for example, see Patent Document 1). That is, it is to obtain an in-focus image, an image with an appropriate exposure, an image without blur, and an image with an appropriate color balance. Alternatively, one image can be obtained by one photographing, and the uniform image can be obtained on the screen. That is to get the exposure screen.
[0003]
However, on the other hand, with the diversification of values, taking low-quality, low-reliability silver halide film cameras as quaint or playful images is another field. It is being established. For example, a blurred image, an underexposed or overexposed image, a blurred image, an image with an imbalanced color tone, or an image obtained by combining them.
[0004]
Similarly, an image in which a trouble caused by a hardware trouble of the photographing apparatus has been positively photographed as having a tasteful or playfulness. For example, an image subjected to multiple exposure, an image having overlapping frames, an image having light leakage, or an image obtained by combining the images.
[0005]
[Patent Document 1]
JP 2001-257977 A
[0006]
[Problems to be solved by the invention]
However, the image to be actively photographed as described above does not necessarily have to simply have a low image quality or a defect, and the degree of the low image quality or the degree of the problem is suppressed to an appropriate range. It had to be a picture that could be appreciated. For that purpose, the user of the photographing apparatus needs to have a certain level of photographing technique and knowledge of the photographing apparatus, and it is not easy to photograph. Moreover, even if the photographing technique and knowledge are used, an interesting or playful image cannot always be obtained.
[0007]
The present invention has been made in view of the above-described problems in the related art, and has a function of easily or intentionally photographing a quaint or playful image having low image quality or a defect. It is intended to provide a control system.
[0008]
[Means for Solving the Problems]
An imaging control system according to the present invention, provided to solve the above problem, captures a depth of field shifted by a predetermined amount from a depth of field based on an appropriate subject distance measured by a distance measuring unit. It is characterized by the condition.
[0009]
With this system, a moderately out-of-focus, so-called out-of-focus, tasteful or playful image can be obtained.
At this time, the degree to which the focus is shifted is determined by a predetermined amount to be shifted from the depth of field, but the predetermined amount is too far out of focus of the lens farther from the far point or closer to the near point of the depth of field. It is advisable to match them so that they do not become pictures. Further, the shift amount may be set in advance or may be changed at random.
Note that the in-focus state means that the subject exists within a range (depth of field) in front of and behind the “absolute focusing distance” where the object is in focus. The depth of field L can be calculated from the object distance OD, the focal length FL of the photographing lens, the aperture value F of the lens at the time of photographing, and the permissible circle of confusion δ. Of these four items, the permissible circle of confusion diameter (the diameter of the largest circle in which a point appears as a point) is a value empirically derived from “observed image size”, “observation distance”, and “human eye resolution”. Has a width depending on the condition. Incidentally, in the case of a silver halide camera, it is set to about 1/1500 of the diagonal size of the imaging plane. Specifically, since the screen size of the 35 mm format is 24 × 36 mm, the diagonal is about 43 mm, and δ ≒ 0.029 mm (about 3/100 mm). In the case of a digital camera, strictly speaking, if one point forms an image over one pixel or more, it can be said that the image is blurred, and the allowable diameter of confusion circle can be said to be the pixel pitch. If interpreted loosely, it is considered that three colors (= 3 pixels) of RGB or YMC represent an object point having one color, and the permissible circle of confusion can be considered as a pixel pitch x3.
[0010]
A photographing control system according to a second aspect of the present invention, provided to solve the above-described problem, sets an exposure amount obtained by shifting a predetermined amount from an appropriate exposure amount based on an external light amount measured by a photometric unit as a photographing condition. Features.
[0011]
With this system, it is possible to obtain a so-called whitish or blackish tasteful or playful image in which the exposure amount is appropriately shifted.
At this time, the degree of shifting the exposure amount is determined by a predetermined amount to be shifted from the proper exposure amount, and the predetermined amount is shifted to an under or over direction from the proper exposure amount by adjusting the aperture or strobe light control to a pure black or pure white picture. It is advisable to make adjustments just before they do. Further, the shift amount may be set in advance or may be changed at random.
[0012]
An imaging control system according to a third aspect of the present invention, which is provided to solve the above-described problem, is characterized in that imaging conditions for moving the blur correction mechanism to be equal to or larger than the permissible circle of confusion are set.
[0013]
With this system, a moderately blurred, quaint, or playful image can be obtained.
To move the shake correction mechanism is to intentionally move a part of the photographing lens or the image plane itself. Where one point on the subject should be focused on one point on the image plane, the permissible confusion. The photographing conditions are set so as to move more than the circle diameter. Further, the moving amount may be set in advance, or may be changed at random by using random number generation.
[0014]
An image capturing control system according to an embodiment of the present invention, provided to solve the above-described problem, includes an image captured based on a color temperature shifted by a predetermined amount from a color temperature serving as a reference for white balance adjustment of image data. It is characterized in that the balance of the ratio of the RGB output components of the data is adjusted.
[0015]
With this system, it is possible to obtain a tasteful or playful image with an improperly balanced color development.
Note that this shooting condition is a condition applied only to a digital camera that performs signal processing on image data after shooting, and adjusts the ratio of each output component of RGB so that white is generated as white in the auto white balance. By changing the reference color temperature W (5500K in this case), the white balance is shifted. Further, the selection of the shift degree may be set in advance, or may be changed at random using the generation of random numbers.
[0016]
A photographing control system according to a fifth aspect of the present invention is provided for solving the above-mentioned problems. In a photographing control system for recording a plurality of exposures on the same screen, the effect weight adjustment is performed by setting a multiple exposure number and / or exposing. It is characterized by performing by adjusting.
[0017]
With this system, a quaint or playful image can be obtained by adjusting the degree of multiple exposure as a multiple exposure image.
Further, according to this system, it is possible to simulate a defect phenomenon which occurs only in a camera using a film, even in a digital camera.
[0018]
7. A shooting control system according to claim 6, which is provided to solve the above-described problem. In a shooting control system that records a plurality of exposures on the same screen, a frame to which weight adjustment of the effect is to be repeated and / or a position to be overlapped is designated. It is characterized by performing by specifying.
[0019]
By this system, the degree of the frame overlap is adjusted as the frame overlap image, so that a quaint or playful image can be obtained.
Further, according to this system, it is also possible to simulate a malfunction that occurs only in a camera using a film in a digital camera.
The weight adjustment of the effect based on the designation of the frame to be overlapped and the designation of the position of the overlap may be set in advance by the user, or may be the adjustment of the weight set in advance using the generation of random numbers.
[0020]
According to a seventh aspect of the present invention, there is provided an imaging control system for obtaining an image of a light leak, wherein the weight of the effect is adjusted by designating the intensity of the light and / or entering the light. It is characterized in that it is performed by designating a position and an angle.
[0021]
By this system, the degree of light leakage is adjusted as an image in which light leakage has occurred on the obtained screen, so that a quaint or playful image can be obtained.
Further, according to this system, it is also possible to simulate a defect phenomenon which occurs only in a camera of a type which exposes a film to a film, even in a digital camera.
The weight adjustment of the effect by designating the intensity of the light beam and the position and angle at which the light beam enters may be set in advance by the user, and the preset weight is adjusted by using random number generation. May be used.
[0022]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, a configuration of an imaging control system according to an embodiment of the present invention will be described with reference to the drawings.
Here, a description will be given on the assumption that a digital still camera having an auto focus (AF) function, an auto iris (AE) function, a camera shake correction function, and an auto white balance function (AWB) is provided with a shooting control system according to the present invention. However, the object to which the present invention is applied is not limited to this, and may be any imaging device (a single-lens reflex camera, a video camera, or the like) having at least one of the above functions. In addition, the above-described auto focus (AF) function, auto iris (AE) function, camera shake correction function, and auto white balance function (AWB) may be conventional techniques. Note that the digital still camera referred to here has an optical lens system, an aperture, and an image pickup device (CCD) as image pickup means, and the shutter operates when a release button provided on the still camera is pressed in two steps. Then, a subject image is formed on an image sensor via an optical lens and an aperture set under predetermined shooting conditions. In addition, it is provided with photometric means for measuring the brightness of external light by pressing the shutter button in the first stage, distance measuring means for measuring the distance to the subject, and the like. Further, a known signal processing unit including a correlated double sampling unit for processing an image signal obtained by the imaging unit, an auto gain control unit, an A / D conversion unit, and a digital signal processing unit is provided.
[0023]
FIG. 1 is a flowchart showing a flow of operation and shooting control in a low image quality mode in a digital still camera including a shooting control system according to the present invention.
Hereinafter, the configuration and operation will be described with reference to FIG.
In the case of the low image quality photographing mode, the photographing control system may be switched from the normal automatic image capturing mode to the low image quality mode by operating the mode switching unit of the digital still camera. Further, there is no problem even if the configuration is such that the low image quality mode is set immediately after the power is turned on. When switching to the low image quality mode, an automatic low image quality mode, a random low image quality mode, and a manual low image quality mode can be selected. Alternatively, when applied to individual products, there is no problem even if only one of the low image quality modes is adopted.
Hereinafter, each of the low image quality modes will be described.
[0024]
(1) Automatic low image quality mode
When the automatic low image quality mode is selected, the imaging system is controlled in a state where both the random low image quality mode and the manual low image quality mode are OFF.
In photographing, when the user half-presses the shutter button (first step down), the first release RL1 is turned on (S101), and the distance to the subject is detected by sensors of an automatic mechanism such as a distance measuring unit, a light measuring unit, and a blur detection. The measurement and detection of the distance, the brightness of external light, and the like are performed (S102).
Appropriate values (depth of field L, EV value E, image surface speed V, color temperature W) are determined based on the measurement and detection results (S103).
[0025]
Of the appropriate values, the depth of field L is the near point L of the depth of field obtained from the distance to the subject or the like._NFar point L from_FIt has a range up to. Specifically, the near point L of the depth of field_N, Far point L_FIs obtained by the following equation.
L_N= (OD '* OD) / (OD' + OD) ... (1)
L_F= (OD '* OD) / (OD'-OD) ... (2)
Here, OD is the object distance, FL is the focal length of the photographing lens, F is the optimum aperture value of the lens at the time of photographing, δ is the permissible circle of confusion, OD ′ = (FL * FL / (δ * F)) * OD It is. The image plane speed V is a speed component (mm / sec) parallel to the image plane at the image point.
[0026]
Next, by confirming the state of the low image quality mode ON (S104) and the state of the random mode OFF (S105), constants a = 1, b = 1, c = 1, d in the following equations (3) to (6). = 1 and the AF shift amount S_AF, AE shift amount S_AE, Correction coefficient K for blur correction, AWB shift amount S_AWBIs determined (S107).
[0027]
S_AF= K1 * a = K1 ... (3)
S_AE= K2 * b = K2 ... (4)
K = K3 * c = K3 ... (5)
S_AWB= K4 * d = K4 ... (6)
[0028]
It should be noted that the values of K1 to K4 at this time are constants set in advance before shooting, and are automatically set by the shooting control system. Alternatively, it may be set by selection from a constant table or numerical input by the user.
[0029]
Next, when the state of the manual mode OFF (S108) is confirmed, shooting of the depth of field L1, the EV value E1, the image plane speed V1, and the color temperature W1 is performed according to the following equations (7) to (10). The condition is calculated (S110).
[0030]
L1 = L + K1 ... (7)
E1 = E + K2 ... (8)
V1 = V + K3 ... (9)
W1 = W + K4 ... (10)
[0031]
After that, the imaging mechanism such as the lens barrel of the still camera and the aperture of the shutter is driven and adjusted in order to set the focus and iris to the imaging conditions based on the above equations (7) to (9), and the camera is ready for imaging (S111). .
When the second release RL2 is turned on by the user further pressing the shutter button (depressing in the second stage) (S112), the subject image is exposed on the CCD under predetermined shooting conditions (S113). The captured image data is subjected to white balance adjustment by signal processing means based on the calculated color temperature W1, and other predetermined signal processing is performed. The image data after the signal processing is displayed on the liquid crystal screen of the digital still camera, recorded in a memory or the like as necessary, and the shooting is completed.
In the above description, the photographing conditions (depth of field L1, EV value E1, image plane speed V1, color temperature W1) are all set, and photographing is performed. However, only one of these photographing conditions is used. Alternatively, an arbitrary combination of imaging conditions may be selected automatically or by the user's intention, and other imaging conditions may be set to appropriate values.
The driving of the focus and the iris may be performed after the second release RL2 is turned on.
In the shooting control system, shooting conditions are shifted by a predetermined size from an appropriate value calculated based on a result measured by a sensor of the automatic mechanism, and a certain low-quality image is stably obtained. It is obtained.
[0032]
(2) Random low image quality mode
When the random low image quality mode is selected, the following control is performed so that the combination of the above-described individual elements for lowering the image quality and the weight of the effect changes every photographing.
At the time of shooting, when the first release RL1 is turned on (S101), the sensor of the automatic mechanism is measured and detected (S102), and appropriate values (depth of field L, EV value E, image surface speed V, color temperature W) are obtained. Is the same as in the automatic low image quality mode until S is determined (S103).
[0033]
Then, by confirming the state of the low image quality mode ON (S104) and the random mode ON (S105), each of the constants a to d is determined based on the random number generation within a numerical range determined by each of the constants a to d. Is set (S106). AF shift amount S_AF, AE shift amount S_AE, Correction coefficient K for blur correction, AWB shift amount S_AWBIs determined according to the following equations (11) to (14) (S107). As a result, the shift amount and coefficient change randomly each time shooting is performed.
[0034]
S_AF= K1 * a ... (11)
S_AE= K2 * b ... (12)
K = K3 * c ... (13)
S_AWB= K4 * d ... (14)
[0035]
It should be noted that the values of K1 to K4 at this time are constants set in advance before shooting, and are automatically set by the shooting control system. Alternatively, it may be set by selection from a constant table or numerical input by the user.
[0036]
Next, when the state of the manual mode OFF (S108) is confirmed, shooting of the depth of field L1, the EV value E1, the image plane speed V1, and the color temperature W1 is performed according to the following equations (15) to (18). The condition is calculated (S110).
[0037]
L1 = L + K1 * a ... (15)
E1 = E + K2 * b ... (16)
V1 = V + K3 * c ... (17)
W1 = W + K4 * d ... (18)
[0038]
After that, the imaging mechanism such as the lens barrel of the still camera and the aperture of the shutter is driven and adjusted in order to set the focus and iris to the photographing conditions based on the above equations (15) to (17), and the photographing is ready (S111). .
When the second release RL2 is turned on by the user further pressing the shutter button (depressing in the second stage) (S112), the subject image is exposed on the CCD under predetermined shooting conditions (S113). The captured image data is subjected to white balance adjustment by signal processing means based on the calculated color temperature W1, and other predetermined signal processing is performed. The image data after the signal processing is displayed on the liquid crystal screen of the digital still camera, recorded in a memory or the like as necessary, and the shooting is completed.
In the above description, the photographing conditions (depth of field L1, EV value E1, image plane speed V1, color temperature W1) are all set, and photographing is performed. However, only one of these photographing conditions is used. Alternatively, an arbitrary combination of imaging conditions may be automatically selected at random or by the user's intention, and other imaging conditions may be set to appropriate values.
In the random low image quality mode, a low quality image in which the image quality is not constant is obtained every time shooting is performed, and the possibility of obtaining an unexpected and unexpected image quality reduction effect increases. The strength of the entire effect may be selected by the user as in the automatic low image quality mode.
[0039]
(3) Manual low image quality mode
In the manual low image quality mode, the operation of each item of the shooting conditions and the weight of the effect can be selected by the user.
In this case, in FIG. 1, from the start of shooting to step S107, the operation and the operation are the same, and the mode may be any of the automatic low image quality mode and the random low image quality mode. The operation after step 108 will be described.
[0040]
When the state of manual mode ON (S108) is confirmed, the constants a to d set by the user are applied to the equations (11) to (14) to obtain the AF shift amount S._AF, AE shift amount S_AE, Correction coefficient K for blur correction, AWB shift amount S_AWBIs determined (S109). The setting of the constants a to d may be performed at the time when the state of the manual mode ON (S108) is confirmed (during the shooting), but is set when the manual low image quality mode is selected before the shooting. Is also good. Then, according to the equations (15) to (18) to which the equations (11) to (14) using the constants a to d set by the user are applied, the depth of field L1, the EV value E1, the image The photographing conditions of the surface speed V1 and the color temperature W1 are calculated (S110).
[0041]
After that, the imaging mechanism such as the lens barrel of the still camera and the aperture of the shutter is driven and adjusted in order to set the focus and iris to the imaging conditions based on the above equations (15) to (17), and a shooting preparation state is established (S111). .
When the second release RL2 is turned on by the user further pressing the shutter button (depressing in the second stage) (S112), the subject image is exposed on the CCD under predetermined shooting conditions (S113). The captured image data is subjected to white balance adjustment by signal processing means based on the calculated color temperature W1, and other predetermined signal processing is performed. The image data after the signal processing is displayed on the liquid crystal screen of the digital still camera, recorded in a memory or the like as necessary, and the shooting is completed.
In the above description, the photographing conditions (depth of field L1, EV value E1, image plane speed V1, color temperature W1) are all set, and photographing is performed. However, only one of these photographing conditions is used. Alternatively, an arbitrary combination of photographing conditions may be selected by the user's intention, and other photographing conditions may be set to appropriate values.
[0042]
In addition, in step 109, the user may be allowed to arbitrarily set the function regarding the photographing condition. For example, for the AE, the user can select from three options of “function properly”, “turn off”, and “shift from an appropriate value”, and if the user selects to shift from the appropriate value, the user May be configured to input the shift amount and direction and adjust the degree of the image quality reduction effect. Further, when a combination that provides the effect desired by the user can be set, the combination may be stored in the camera by a recording unit (not shown) so that the combination can be called up later.
[0043]
(4) Normal shooting mode
When the normal shooting mode is selected by operating the mode switching unit of the still camera, the low image quality mode is turned off, and normal automatic shooting can be performed.
In the case of normal photographing, appropriate values (object distance L, EV value E, image plane speed V, color temperature W) based on the detection result determined in step S103 are set as photographing conditions as they are, and a still image is formed based on the conditions. The image pickup mechanism such as the lens barrel of the camera and the aperture of the shutter is driven and adjusted, and the apparatus enters a shooting preparation state (S111).
Next, when the second release RL2 is turned on by the user further pressing the shutter button (the second step of depression) (S112), the subject image is exposed on the CCD under predetermined shooting conditions (S113). The captured image data is subjected to white balance adjustment based on an appropriate color temperature W, and is subjected to other predetermined signal processing. The image data after the signal processing is displayed on the liquid crystal screen of the digital still camera, recorded in a memory or the like as necessary, and the shooting is completed.
[0044]
(Example)
An example in which shooting conditions are set for the low image quality mode in the shooting control system according to the present invention will be described below.
(A) Depth of field L1
In the above equation (15), the coefficient and the constant are set after the maximum value or the minimum value of the appropriate range is selected for the depth of field L. Here, the far point L as the depth of field L_FIs selected, K1 = L_F, 0 <a ≦ 1. Also, the near point L as the depth of field L_NIs selected, K1 = L_N, −0.5 ≦ a <0.
That is,
L1 = L_F+ L_F* A (0 <a ≦ 1)
L1 = L_N+ L_N* A (-0.5 ≦ a <0)
And Far point L with depth of field L_F, Near point L_NIs selected in, for example, the far point L in the automatic low image quality mode._FMay be selected, and in the random low image quality mode, either one may be selected using the random number generation in step S106, and in the manual low image quality mode, the user may be able to select in advance.
[0045]
This is based on the following concept.
That is, when the subject distance is OD in the above equations (1) and (2), L_FMore distant or L_NWhen the lens is focused on the closer side, the subject image on the CCD (or on the image plane) is blurred. Considering the case where the image is too blurred to produce a picture, the value L1 deviating from the appropriate value for the purpose of the present invention preferably has the following range.
L_F<L1 ≦ 2 * L_F
L_N> L1 ≧ 0.5 * L_N
The setting of the coefficient and the constant related to the AF shift amount is based on these two equations.
[0046]
(B) EV value E1
Regarding the AE shift amount, a constant to be set differs depending on the type of the applied imaging device or the type of the film. This is due to the difference in the extent of the allowable range of exposure.
That is, in the case of a digital camera or a camera using a positive film, the allowable range of exposure is narrow, and the above equation (16) becomes as follows.
E1 = E + K2 * b (K2 = ± 1, 0.5 ≦ b ≦ 2.5)
In the case of a camera using a negative film, since the allowable range of exposure is wide, the above equation (16) becomes as follows.
E1 = E + K2 * b (K2 = ± 1, 2 ≦ b ≦ 5)
The selection of the value of K2 is, for example, such that K2 = 1 is selected in the automatic low image quality mode, and one of them is selected in the random low image quality mode by using the random number generation in step S106. In the mode, the user may be allowed to select in advance.
[0047]
(C) Image plane speed V1
The above equation (17) is as follows.
V1 = V + K3 * c (K3 = δ / T, 0 ≦ c ≦ 5)
Here, V is a correctable image surface speed, that is, an appropriate image surface speed (mm / sec), and V = δ / T. Δ is the permissible circle of confusion (mm), and T is the exposure time (sec).
This photographing condition is such that an image blurred by intentionally moving a part of the photographing lens or the image plane itself beyond the permissible circle of confusion when one point on the object should originally form an image on one point on the image plane. Is to create It should be noted that 6δ is an upper limit in consideration of a case where the image is not blurred due to blur.
[0048]
(D) Color temperature W1
The above equation (18) is as follows.
W1 = W + K4 * d (K4 = ± 1500, 1 ≦ d ≦ 1.6)
This shooting condition is a condition that is applied only to a digital camera that performs signal processing on image data after shooting, and is a reference for adjusting the ratio of each output component of RGB so that white appears as white in the auto white balance. The white balance is shifted by changing the color temperature W (5500K in this case).
The value of K4 is selected, for example, such that K4 = 1500 is selected in the automatic low image quality mode, and one of them is selected in the random low image quality mode by using the random number generation in step S106. In the image quality mode, the user may be allowed to select in advance.
[0049]
Next, the configuration of another embodiment of the imaging control system according to the present invention will be described with reference to the drawings.
FIG. 2 is a flowchart showing a flow of operation and shooting control in the failure occurrence mode in the digital still camera including the shooting control system according to the present invention. The target to which the shooting control system according to the present invention is applied is not only applied to an imaging apparatus having a process such as a digital still camera, which can perform post-processing by performing signal processing after shooting image data. Any type of imaging device (single-lens reflex camera, video camera, etc.) may be used. Note that the digital still camera referred to here has an optical lens system, an aperture, and an image pickup device (CCD) as image pickup means, and the shutter operates when a release button provided on the still camera is pressed in two steps. Then, a subject image is formed on an image sensor via an optical lens and an aperture set under predetermined shooting conditions. In addition, there are provided photometric means for measuring the brightness of external light by pressing the shutter button in the first stage, and distance measuring means for measuring the distance to the subject. Further, a known signal processing unit including a correlated double sampling unit for processing an image signal obtained by the imaging unit, an auto gain control unit, an A / D conversion unit, and a digital signal processing unit is provided.
[0050]
Hereinafter, the configuration and operation will be described with reference to FIG.
In the case of the failure occurrence mode, the imaging control system may be switched from the normal automatic imaging mode to the failure occurrence mode by operating the mode switching unit of the digital still camera. In addition, there is no problem if the trouble occurrence mode is configured immediately after the power is turned on. Automatic defect generation mode that automatically generates a defect when switching to the defect generation mode, random defect generation mode that randomly generates and combines the combination of effects and effect weights, and manual defect that allows you to manually select the item and effect of the defect The generation mode can be selected. Alternatively, when applied to individual products, there is no problem even if only one of the failure occurrence modes is adopted.
The operation flow for each mode is basically the same as the low image quality mode.
[0051]
(1) Automatic failure occurrence mode
When the automatic failure occurrence mode is selected, the imaging system is controlled in a state where both the random failure occurrence mode and the manual failure occurrence mode are OFF.
In photographing, when the user half-presses the shutter button (first step down), the first release RL1 is turned on (S201), and sensors of an automatic mechanism such as a distance measuring unit, a light measuring unit, and a blur detection are provided to the subject. The measurement and detection of the distance of the object and the brightness of the external light are performed (S202).
Appropriate values (depth of field L, EV value E, image surface speed V, color temperature W) are determined based on the measurement and detection results (S203).
[0052]
Next, by confirming the states of the failure occurrence mode ON (S204) and the random mode OFF (S205), one of the failure items of multiple exposure, frame overlap, and light leakage is turned on, and the failure item that has been turned on is displayed. Weights are set (S207).
[0053]
The weight of each defect item is a constant that is set before photographing, and is automatically set by the photographing control system. Alternatively, it may be set by selection from a constant table or numerical input by the user.
[0054]
The appropriate values (depth of field L, EV value E, image plane speed V, color temperature W) based on the detection result determined in step S203 are taken in parallel with or after the setting of the above-mentioned trouble item. The conditions are set, and based on the conditions, the image pickup mechanisms such as the lens barrel of the still camera and the aperture of the shutter are driven and adjusted, and the apparatus is ready for shooting (S211).
Next, when the second release RL2 is turned on by the user further pressing the shutter button (the second stage depression) (S212), the subject image is exposed on the CCD under predetermined photographing conditions (S213).
[0055]
At the same time as or before the photographing operation, the state of the manual mode OFF (S208) is confirmed, and the image data photographed at the step S213 is processed at the signal processing stage in accordance with the condition of the defect item set at the step S207. It is synthesized (S210). Note that multiple exposure and frame overlap are synthesized using image data captured up to that time. Next, the defective image data after the signal processing is displayed on the liquid crystal screen of the digital still camera, recorded in a memory or the like as necessary, and the photographing ends (S214).
The driving of the focus and the iris may be performed after the second release RL2 is turned on.
In the above-described photographing control system, a defect adjusted based on a preset weight is generated, and an image of a certain defect is stably obtained.
[0056]
(2) Random failure occurrence mode
When the random defect occurrence mode is selected, the following control is performed so that the combination of the individual elements causing the above-described defect and the weight of the effect changes for each photographing.
At the time of photographing, when the first release RL1 is turned on (S201), measurement and detection of the sensor of the automatic mechanism are performed (S202), and appropriate values (depth of field L, EV value E, image surface speed V, color temperature W). Is the same as that in the automatic failure occurrence mode until S is determined (S203).
[0057]
Next, by confirming the state of the failure occurrence mode ON (S204) and the random mode ON (S205), the constants a to c corresponding to the failure item are within the numerical ranges determined by the constants a to c, respectively. , A numerical value based on the random number generation is set, and at the same time, ON / OFF of each fault item is determined using the random number generation (S206). Among the defect items of multiple exposure, frame overlap, and light leakage, the item determined in step S206 is turned ON, and the weights of the turned ON defect items are added with constants a to c to the preset weights. It is set (S207). As a result, the occurrence and degree of each defect randomly change each time shooting is performed.
The photographing control in the subsequent steps is the same as in the above-described automatic failure occurrence mode. In the random defect generation mode, an image having a defect in which the degree of the defect is not constant is obtained each time shooting is performed, and the possibility of obtaining a surprising defect generation effect that is unexpected to the user is increased.
[0058]
(3) Manual failure mode
In the manual failure occurrence mode, the operation of the failure item and the weight of the effect can be selected by the user.
In this case, in FIG. 2, from the start of shooting to the step SS07, the operation and the operation are the same as those described above. The operation contents of steps S208 and S209 will be described.
[0059]
By confirming the state of manual mode ON (S208), the trouble item selected by the user is turned ON, and the weight of the trouble item turned ON is set by the user to a preset weight. The calculated constants a to c are taken into account and set (S209). The constants a to c may be set at the time when the state of manual mode ON (S208) is confirmed (during shooting), but may be set at the time of selection of a manual failure occurrence mode before shooting. Is also good.
The photographing control in the subsequent steps is the same as in the above-described automatic failure occurrence mode.
[0060]
The contents of each defect will be described below.
(B) Multiple exposure effect
In the case of a digital camera, a multiple exposure effect can be obtained by synthesizing a plurality of pieces of captured image data after setting the mode. In the case of a silver halide film camera, a plurality of exposures are recorded on the same screen by stopping the film feed. At this time, the setting of the number of multiple exposures and the adjustment of the exposure are performed in the form of effect weight adjustment.
[0061]
(B) Frame overlap
Both the digital camera and the silver halide film camera can be basically performed by the same processing as the multiple exposure. However, by adjusting the weight, the frame to be overlapped (captured image) and the position to overlap are designated.
[0062]
(C) Ray leakage
In the case of a digital camera, a light source may emit light to partially expose an image, or only the light leakage may be stored in the camera in advance, and the image may be synthesized later. In the case of a silver halide film camera, an operation may be performed to temporarily break the state of the dark box. Alternatively, a light source may emit light to expose a part of the film. In such a case, a light source may be newly provided, or a structure may be adopted in which light from a light source already built in the camera, such as an AF assist / strobe / date imprinting LED, is guided to the photosensitive surface. However, by adjusting the weight, the intensity of the light beam and the position and angle at which the light beam enters are specified.
[0063]
【The invention's effect】
As described above, it is possible to obtain a photographing control system capable of automatically photographing a low-quality photograph as if photographed by a low-quality camera, regardless of whether the film is a silver halide film or digital. In addition, it is possible to take a photograph having a low image quality reflecting the intention of the user or a photograph having a defect, a tasteful or playful feeling.
More specifically, according to the first aspect of the present invention, it is possible to obtain a moderately out-of-focus, so-called out-of-focus, tasteful or playful image.
According to the second aspect of the present invention, it is possible to obtain a so-called whitish or blackish or playful image in which the exposure amount is appropriately shifted.
According to the third aspect of the present invention, it is possible to obtain a moderately blurred, quaint, or playful image.
According to the fourth aspect of the present invention, it is possible to obtain a quaint or playful image in which the balance of coloring is moderately broken.
According to the fifth aspect of the present invention, a quaint or playful image can be obtained by adjusting the degree of frame overlap as a frame overlap image. Further, according to this system, it is also possible to simulate a malfunction that occurs only in a camera using a film in a digital camera.
According to the sixth aspect of the present invention, a quaint or playful image can be obtained by adjusting the degree of frame overlap as a frame overlap image. Further, according to this system, it is also possible to simulate a malfunction that occurs only in a camera using a film in a digital camera.
According to the invention of claim 7, by adjusting the degree of light leakage as an image in which light leakage has occurred on the obtained screen, a quaint or playful image can be obtained. Further, according to this system, it is also possible to simulate a defect phenomenon which occurs only in a camera of a type which exposes a film to a film, even in a digital camera.
[Brief description of the drawings]
FIG. 1 is a flowchart showing a flow of operation and shooting control in a low image quality mode in one embodiment of a shooting control system according to the present invention.
FIG. 2 is a flowchart showing a flow of operation and shooting control in a failure occurrence mode in another embodiment of the shooting control system according to the present invention.

Claims (7)

A photographing control system characterized in that a photographing condition is a depth of field shifted by a predetermined amount from an appropriate depth of field based on a subject distance measured by a distance measuring unit. An imaging control system, wherein an exposure amount obtained by shifting a predetermined amount from an appropriate exposure amount based on an external light amount measured by a photometer is used as an imaging condition. A photographing control system, wherein photographing conditions are set to move a blur correction mechanism to a diameter larger than an allowable circle of confusion. A photographing control system, comprising: adjusting a balance of a ratio of each output component of RGB of photographed image data based on a color temperature shifted by a predetermined amount from a color temperature serving as a reference of white balance adjustment of image data. A photographing control system for recording a plurality of exposures on the same screen, wherein the effect weight adjustment is performed by setting the number of multiple exposures and / or adjusting the exposure. An imaging control system for recording a plurality of exposures on the same screen, wherein weight adjustment of the effect is performed by designating a frame to be overlapped and / or by specifying a position to be overlapped. An imaging control system for obtaining an image of light leakage, wherein the weight adjustment of the effect is performed by designating the intensity of the light beam and / or the position and angle at which the light beam enters.

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