WO2023008146A1 - 撮影条件調整装置、撮影条件調整方法及びプログラム - Google Patents
撮影条件調整装置、撮影条件調整方法及びプログラム Download PDFInfo
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- 239000000758 substrate Substances 0.000 description 2
- NAWXUBYGYWOOIX-SFHVURJKSA-N (2s)-2-[[4-[2-(2,4-diaminoquinazolin-6-yl)ethyl]benzoyl]amino]-4-methylidenepentanedioic acid Chemical compound C1=CC2=NC(N)=NC(N)=C2C=C1CCC1=CC=C(C(=O)N[C@@H](CC(=C)C(O)=O)C(O)=O)C=C1 NAWXUBYGYWOOIX-SFHVURJKSA-N 0.000 description 1
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- G01N21/84—Systems specially adapted for particular applications
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- the present invention relates to a plurality of photographed images obtained by photographing a work illuminated by a lighting device with a camera while at least one of the lighting device and the camera is moved relative to a work such as a vehicle body.
- TECHNICAL FIELD The present invention relates to a photographing condition adjusting device, a photographing condition adjusting method, and a program for adjusting photographing conditions.
- Patent Document 1 describes creating a histogram of each image and using the luminance average value of the two peaks corresponding to the bright and dark portions as the binarization level threshold.
- Patent Document 2 discloses controlling the exposure time according to the characteristic information of the substrate
- Patent Document 3 discloses controlling the exposure time according to the reflectance of the target for photographing.
- Patent Documents 2 and 3 the object to be measured is uniform like a board, and does not have a three-dimensional shape like a car body. For this reason, it is sufficient to set one exposure time for each substrate, and the verification is easy. Since it changes gradually, the techniques of Patent Documents 2 and 3 cannot be applied.
- the present invention has been made in view of such a technical background.
- a photographing condition adjusting device a photographing condition adjusting method, and a program that eliminate the need to confirm a binary image for each of a plurality of photographed images when photographing with a camera.
- the above objects are achieved by the following means.
- Acquisition means for acquiring a plurality of photographed images obtained by photographing a work illuminated by the lighting device with the camera while at least one of the lighting device and the camera is moved relative to the work; an adjustment means for adjusting the photographing conditions of the camera so that the brightness distribution of the images is uniform for each of the plurality of photographed images obtained by the obtaining means; A device for adjusting shooting conditions.
- the photographing condition adjustment device according to the preceding item 1 wherein the photographing conditions include an exposure time of the camera.
- the adjusting means adjusts the maximum amount of light in the dark area of the photographed image to a constant value, the minimum amount of light in the light band to a constant value, or the maximum amount of light in the dark area and the minimum amount of light in the light band. 4.
- the photographing condition adjustment device according to any one of the preceding items 1 to 3, which adjusts the photographing conditions so that the intermediate light amount of is a constant value.
- the photographing condition adjusting apparatus according to any one of the preceding items 1 to 4, wherein the adjusting means adjusts the photographing conditions so that the maximum amount of light in the light band in the photographed image does not exceed an upper limit value.
- the photographing condition adjustment device according to any one of claims 1 to 5, further comprising: (7) The photographing condition adjustment device according to the preceding item 6, wherein the parameter is color coding. (8) The photographing condition adjustment device according to the preceding item 6, wherein the parameter is a gradation. (9) The photographing condition adjusting apparatus according to any one of the preceding items 6 to 8, wherein the display data is display data in which the one-dimensional histograms are displayed in a dense array. (10) The photographing condition adjustment device according to any one of the preceding items 6 to 8, wherein the display data is display data in which thinned-out one-dimensional histograms are displayed side by side.
- the photographing condition adjusting apparatus according to the above item 10, wherein the photographing conditions for the thinned frame are diverted from the photographing conditions obtained for the used frames before and after the thinned frame.
- Shooting condition adjustment method including.
- the maximum amount of light in the dark area in the photographed image is set to a constant value, or the minimum amount of light in the light band is set to a constant value, or the maximum amount of light in the dark area and the minimum amount of light in the light band are set to a constant value.
- the photographing conditions of the camera are adjusted so that the brightness distribution of the image is uniform for each of the plurality of photographed images obtained. This eliminates the need to check the binarized image for each photographed image.
- the exposure time of the camera is adjusted so that the brightness distribution of the image is uniform.
- the gain of the camera is adjusted so that the brightness distribution of the image is uniform.
- the maximum amount of light in the dark area in the photographed image is set to a constant value, or the minimum amount of light in the light band is set to a constant value, or the dark area is set to a constant value.
- the photographing conditions are adjusted so that the intermediate amount of light between the maximum amount of light and the minimum amount of light in the light band is constant.
- the shooting conditions are adjusted so that the maximum amount of light in the light band in the shot image does not exceed the upper limit.
- one-dimensional histograms of a plurality of captured images can be displayed side by side.
- the photographing conditions for the thinned frames are diverted from the photographing conditions obtained for the used frames before and after the thinned frames, so that the photographing condition adjustment process is simplified. be.
- a plurality of photographed images obtained by photographing the work illuminated by the lighting device with the camera while at least one of the lighting device and the camera is moved relative to the work. is obtained, and the computer can be caused to execute a process of adjusting the photographing conditions of the camera so that the brightness distribution of the images is uniform for each of the obtained plural photographed images.
- FIG. 1 is a schematic configuration diagram of an imaging system using data processing according to an embodiment of the present invention
- FIG. (A) to (F) are images captured by a camera continuously while the vehicle body is moving. The position of the vehicle body and the photographed image thereof are shown when photographing is performed under uniform exposure conditions, (A) to (C) are the photographed images, and (D) is the image of the vehicle body.
- (A) to (C) are binarized images obtained when the captured images of FIGS. 3A to 3C are binarized with a constant binarization threshold.
- (A) to (C) show captured images with adjusted shooting conditions, and (D) is an image of the vehicle body.
- (A) to (C) are binarized images obtained from the captured images of FIGS. 5A to 5C.
- FIG. 8 is a diagram showing a histogram of the captured image of FIG. 7;
- FIG. FIG. 10 is an explanatory diagram of a case where histogram frequencies are displayed in different colors;
- FIG. 10 is an explanatory diagram of a case where histogram frequencies are displayed in gradation;
- FIG. 10 is a diagram showing a one-dimensional histogram created by displaying the frequencies of the histogram in different colors;
- FIG. 10 is an explanatory diagram of a case where a plurality of one-dimensional histograms obtained by thinning an image are arranged and displayed; It is a figure which shows an example of the histogram of a picked-up image.
- FIG. 10 is an explanatory diagram of a case where one-dimensional histograms of all captured images before adjustment of imaging conditions are arranged and displayed; 7 is a graph showing the exposure time for each photographing when the exposure time is adjusted so that the distribution of brightness of the photographed image becomes uniform.
- FIG. 11 is an explanatory diagram of a case where one-dimensional histograms of all captured images after adjustment of shooting conditions are arranged and displayed in order of shooting; (A) shows an original image under a certain photographing condition, and (B) shows an image under another photographing condition for obtaining a histogram.
- FIG. 10 is a diagram showing another example of a histogram of a captured image;
- FIG. 10 is a diagram showing another example of a histogram of a captured image;
- FIG. 1 is a schematic configuration diagram of a photographing system using a photographing condition adjustment device according to one embodiment of the present invention.
- This imaging system is a system used for inspecting the presence or absence of concave or convex defects on the surface of a vehicle body 100 of an automobile, which is a work.
- the photographing system includes a light source 1 as an illumination device, a camera 2 having an image sensor having a large number of pixels, and a data processing device 3 as a photographing condition adjustment device for processing images photographed by the camera 2. . Then, while the vehicle body 100 is illuminated with illumination light from the light source 1, at least one of the light source 1 and the camera 2 is moved relative to the vehicle body 100, and a plurality of frames (for example, about 1000 frames) are captured by the camera 2.
- a plurality of frames for example, about 1000 frames
- the data processing device 3 is configured by a personal computer (PC) in this embodiment.
- the data processing device 3 operates when a processor such as a CPU operates according to an operation program stored in a storage unit (not shown). It includes a creation unit 33, a data output unit 34, an imaging condition adjustment unit 36, and a display device 35 as a display.
- An image acquisition unit 31 acquires images continuously captured by the camera 2
- a histogram creation unit 32 creates a histogram for each captured image
- a one-dimensional histogram creation unit 33 creates a one-dimensional histogram
- data The output unit 34 creates display data for arranging and displaying the created one-dimensional histograms, and outputs the display data to the display device 35, the external printer 4, or the like. are adjusted, and these processes will be described later.
- FIGS. 2A to 2F are captured images taken continuously by the camera 2 while the vehicle body 100 is moving. These captured images are output from the camera 2 and acquired by the data processing device 3. Acquired by unit 31 . While moving the vehicle body 100, the light band 10 of the light source 1 reflected on the vehicle body 100 is detected on the photographed image, and the defect image in the light band 10 is detected. Along with the movement of the vehicle body 100, the position of the light band 10 within the captured image is also gradually moving.
- the vehicle body 100 Since the vehicle body 100 has a complicated three-dimensional shape, the brightness of the light band 10 reflected in the captured image differs for each captured image. Therefore, when creating a binarized image for detecting the light band 10, if the binarization threshold is fixed, the light band cannot be detected well in the binarized image in the photographed image in which the light band 10 appears dark. On the other hand, in a photographed image in which the light band 10 appears brightly, the light band 10 can be correctly detected in the binary image.
- FIG. 3 shows the position of the vehicle body 100 and its captured image when the image was taken under uniform exposure conditions, where (A) to (C) are captured images and (D) is an image of the vehicle body 100. be.
- the captured image 21a in FIG. 3A is a captured image of the front portion of the vehicle body 100 as shown in FIG. 3D
- a photographed image 21 c in FIG. 3C is a photographed image of the rear portion of the vehicle body 100 .
- the light band 10 is shown in each photographed image, it can be seen that the brightness of the light band 10 shown in the photographed image differs depending on the photographing position of the vehicle body 100 .
- FIGS. 4A to 4C are binarized images obtained when the captured images 21a to 21c in FIGS. 3A to 3C are binarized with a constant binarization threshold. 22a-22c are shown respectively.
- the binarized image 22a of FIG. It can be seen that the light band 10 cannot be detected well as in the valued image 22c.
- FIGS. 6A to 6C show binarized images 24a to 24c obtained from the captured images of FIGS. 5A to 5C.
- the photographing conditions can be set so that the brightness of the light band 10 is uniform for all photographed images, it is possible to obtain a correct binarized image even with a constant binarization threshold for all photographed images. .
- the distribution of the brightness of the photographed images differs for each photographing, and the distribution of the brightness of all the photographed images cannot be grasped at a glance. , can be grasped at a glance and is very useful.
- FIG. 7 shows one shot image 25 shot by the camera 2 and acquired by the image acquisition unit 31 of the data processing device 3 .
- the black areas 11 are dark areas, and the bright striped areas are light bands 10 .
- a histogram such as that shown in FIG. 8 is used to represent the brightness distribution of an image.
- the horizontal axis of the histogram is the class, which represents the pixel values of the captured image in this embodiment.
- the vertical axis is the frequency, which in this embodiment is the number of pixels having that pixel value in the captured image.
- FIG. 8 is a histogram of the photographed image 25 of FIG.
- the peak near the pixel value of zero is the dark region 11 and the peak near the pixel value of 50 is the light band 10 .
- FIG. 8 there is a peak due to the light band 10 near the pixel value 50 of the his
- the one-dimensional histogram creation unit 33 creates a one-dimensional histogram by making the histogram one-dimensional.
- One-dimensionalization is performed by using a parameter that can express the frequency of a histogram indicating the distribution of brightness so that the magnitude of the frequency can be identified.
- this parameter is color coding
- the histogram frequencies are displayed in different colors.
- color-coded display of histogram frequencies is also referred to as pseudo-color display.
- the pseudo-color display is based on the magnitude of the value, such as red when the value (frequency) is large, green when the value is intermediate, and blue when the value is small. It does so by displaying it in the assigned color.
- the parameter may be a gradation such as monochrome as shown in FIG. 10 instead of color coding.
- the value (frequency) when the value (frequency) is large, it is displayed in a light color, and when the value is small, it is displayed in a dark color.
- the parameter when the parameter is color coding will be described.
- the histogram in FIG. 8 When the histogram in FIG. 8 is displayed in pseudo-color according to the value (frequency), it becomes as shown in FIG.
- the horizontal axis is the pixel value, which is the class, and the parameter is displayed in the direction of the pixel value.
- the histogram displayed one-dimensionally as shown in FIG. 11 is called a one-dimensional histogram 5 .
- a one-dimensional histogram 5 is created for each captured image. After creation, the horizontal strip-shaped one-dimensional histogram 5 is made vertical, and the one-dimensional histogram 5 is arranged so that the horizontal axis is the photographing frame number, which is the number of the photographed image, and the vertical axis is the pixel value. 14 or FIG. 16, one-dimensional histograms 5 of a large number of captured images can be collectively displayed. Note that the name of the horizontal axis, "Frame No.”, the name of the vertical axis, "Pixel Value", a scale, etc., may also be displayed together.
- FIG. 12 has the advantage of being able to shorten the image reading time and image processing time by thinning out the number of frames, and the display of FIGS.
- the display of the one-dimensional histogram groups as shown in FIGS. 12 and 14 may be performed by printing on the recording medium 6 such as paper by the printer 4 shown in FIG. becomes a display body.
- the one-dimensional histogram group may be displayed on the screen of the display device 35, in which case the display device 35 serves as the display of the one-dimensional histogram group.
- the printing on the recording medium 6 and the display on the display device 34 are performed so that the one-dimensional histograms 5 of all photographed images are displayed side by side, or the one-dimensional histograms 5 of the intermediate photographed images are thinned out and spaced apart.
- the display data output unit 34 creates display data so that it can be displayed, outputs this display data to the printer 4 or the display device 35, which is an image forming device, and prints it on the recording medium 6 by the printer 4 or displays it on the display device. Displayed at 35.
- the display data may be created in PDF (Portable Document Format) or other file formats.
- the display data output unit 34 may transmit the display data to another display device via the network and display the data on the other display device.
- the dark region 11 in the histogram created for each captured image is P1 dark and the maximum pixel value of the light band 10 is P1 light
- the dark region in the histogram of the i-th captured frame A region maximum pixel value P1 dark (i) and a light band maximum pixel value P1 light (i) are obtained.
- the output value PixelValue of each pixel of the imaging element in the camera 2 is obtained by using the light amount L incident on the pixel, the exposure time (ExposureTime), the gain (Gain) of the pixel signal amplification circuit, and the ⁇ value ( ⁇ ). is represented by the following formula (1).
- (1) a in the formula is a coefficient.
- the pixel value P2 when the same amount of light L is incident on the pixel is expressed by the following formula (3).
- the shooting conditions (Gain2, ExposureTime2, ⁇ 2) for each shooting are obtained so that P1 dark (i) becomes a constant value P2 dark for each shooting.
- Gain2 may be fixed and the exposure time ExposureTime2 may be changed for each shooting, or the exposure time ExposureTime2 may be fixed and the gain Gain2 may be changed for each shooting.
- the light amount L may be adjusted by adjusting the brightness of the light source 1, the adjustment becomes complicated, so it is better to change the exposure time ExposureTime2 or the gain Gain2.
- ExposureTime2(i) As shown in formula (4) below.
- the light band maximum pixel value P2 light can be obtained from P1 light using equation (6) described later.
- FIG. 14 shows a one-dimensional histogram of all captured images of a vehicle body 100 captured by the camera 2 without adjusting the capturing conditions. From FIG. 14, it can be seen that the brightness of each photographed image is not uniform and varies greatly unless the photographing conditions are adjusted.
- FIG. 15 shows the exposure time for each photographing obtained by the above equation (4) so that P1 dark (i) becomes a constant value P2 dark for each photographing.
- the pixel value P2 obtained when the shooting conditions are changed from (Gain1, ExposureTime1, ⁇ 1) to (Gain2, ExposureTime2, ⁇ 2) is calculated by formula (6).
- the histogram when the shooting conditions are (Gain2, ExposureTime2, ⁇ 2) is obtained by dividing the original image under the shooting conditions (Gain1, ExposureTime1, ⁇ 1) shown in FIG. 17(a) under the shooting conditions ( Gain2, ExposureTime2, ⁇ 2) may be converted to an image before calculation.
- the histogram of the image obtained under the new exposure conditions can be obtained by simply converting the horizontal axis value (PixelValue) of the histogram of the original image using formula (6).
- the maximum amount of light in the dark region 11 is constant for all captured images, so that the binarized image can be correctly calculated using the binarized threshold common to all captured images. You can tell at a glance.
- the shooting conditions (Gain2, ExposureTime2, ⁇ 2) for each shot were determined so that P1 dark (i) was a constant value P2 dark for each shot, but the minimum light intensity of the light band 10 was constant. It may be controlled so that
- the light band minimum pixel value P1 light_min (i) and the light band maximum pixel value P1 light_max (i) of the i-th frame are obtained from the histogram obtained for each shooting.
- the shooting conditions (Gain2, ExposureTime2, ⁇ 2) for each shooting are obtained so that the light band minimum pixel value P1 light_min (i) becomes a constant value P2 light_min for each shooting.
- Gain2 may be constant and ExposureTime2 may be changed for each frame, or ExposureTime2 may be constant and Gain2 may be changed for each shot.
- P2 light_max can be obtained from P1 light_max using equation (6).
- the intermediate value between the maximum amount of light in the dark area and the minimum amount of light in the light band may be controlled to be a constant value.
- the intermediate value P1 thres (i) between the light band minimum pixel value and the dark region maximum pixel value and the light band maximum pixel value P1 light (i) of the i-th frame are obtained.
- the photographing conditions (Gain2, ExposureTime2, ⁇ 2) for each photographing are obtained so that P1 thres (i) becomes a constant value P2 thres for each photographing.
- Gain2 may be constant and ExposureTime2 may be changed for each frame, or ExposureTime2 may be constant and Gain2 may be changed for each shooting.
- ExposureTime2 may be constant and Gain2 may be changed for each shooting.
- the exposure time is set to ExposureTime2(i) as shown in formula (9).
- P2 light can be obtained from P1 light using equation (6).
- the shooting condition values obtained from the used frames before and after the frames that are not used For example, if the shooting conditions are calculated using the 1st, 6th, 11th, 16th,...th frames, the shooting conditions for the 2nd...5th frames are the shooting conditions obtained using the 1st frames, and the 7th...
- the imaging conditions for the 10th frame are the same as those for the 6th frame.
- the present invention captures a plurality of photographed images obtained by photographing a work illuminated by a lighting device with a camera while at least one of the lighting device and the camera is moved relative to a work such as a vehicle body. Available to adjust conditions.
- Light source (illumination device) 2 camera 3 data processing device (imaging condition adjustment device) 31 image acquisition unit 32 histogram creation unit 33 one-dimensional histogram creation unit 34 data output unit 35 display device (display) 36 photographing condition adjustment unit 4 printer 5 one-dimensional histogram 6 recording medium (display) 10 light band 11 dark area
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Abstract
Description
(1)ワークに対して照明装置とカメラの少なくとも一方を相対的に移動させながら、前記照明装置で照明されたワークを前記カメラで撮影したときの複数枚の撮影画像を取得する取得手段と、
前記取得手段で取得した複数枚の撮影画像毎に、画像の明るさの分布が一様になるように、前記カメラによる撮影条件を調整する調整手段と、
を備えた撮影条件調整装置。
(2)前記撮影条件には、前記カメラの露光時間が含まれる前項1に記載の撮影条件調整装置。
(3)前記撮影条件には、前記カメラのゲインが含まれる前項1に記載の撮影条件調整装置。
(4)前記調整手段は、撮影画像における暗領域の最大光量が一定値となるように、あるいは光帯の最小光量が一定値となるように、あるいは暗領域の最大光量と光帯の最小光量の中間光量が一定値となるように前記撮影条件を調整する前項1~3のいずれかに記載の撮影条件調整装置。
(5)前記調整手段は、撮影画像における光帯の最大光量が上限値を超えないように前記撮影条件を調整する前項1~4のいずれかに記載の撮影条件調整装置。
(6)前記撮影条件の調整前の撮影条件と、調整後の撮影条件の少なくともいずれかの撮影条件で撮影され、前記取得手段で取得した複数枚の撮影画像毎に、撮影画像の明るさの分布を示すヒストグラムの度数を、当該度数の大小を識別可能に表現できるパラメータによりヒストグラムの階級の方向に一次元的に表示した複数個の一次元ヒストグラムを作成する作成手段と、
前記作成手段により作成された複数個の一次元ヒストグラムが並んで表示されるように表示データを出力する出力手段と、
をさらに備えている請求項1~5のいずれかに記載の撮影条件調整装置。
(7)前記パラメータは色分けである前項6に記載の撮影条件調整装置。
(8)前記パラメータはグラデーションである前項6に記載の撮影条件調整装置。
(9)前記表示データは、前記一次元ヒストグラムが密に並んで表示される表示データである前項6~8のいずれかに記載の撮影条件調整装置。
(10)前記表示データは、間引かれた一次元ヒストグラムが並んで表示される表示データである前項6~8のいずれかに記載の撮影条件調整装置。
(11)間引いたフレームにおける撮影条件を、その前後にある使用フレームで求められた撮影条件から流用する前項10に記載の撮影条件調整装置。
(12)ワークに対して照明装置とカメラの少なくとも一方を相対的に移動させながら、前記照明装置で照明されたワークを前記カメラで撮影したときの複数枚の撮影画像を取得する取得ステップと、
前記取得ステップで取得した複数枚の撮影画像毎に、画像の明るさの分布が一様になるように、前記カメラによる撮影条件を調整する調整ステップと、
を含む撮影条件調整方法。
(13)前記撮影条件には、前記カメラの露光時間が含まれる前項12に記載の撮影条件調整方法。
(14)前記撮影条件には、前記カメラのゲインが含まれる前項12に記載の撮影条件調整方法。
(15)前記調整ステップでは、撮影画像における暗領域の最大光量が一定値となるように、あるいは光帯の最小光量が一定値となるように、あるいは暗領域の最大光量と光帯の最小光量の中間光量が一定値となるように前記撮影条件を調整する前項12~14のいずれかに記載の撮影条件調整方法。
(16)前記調整ステップでは、撮影画像における光帯の最大光量が上限値を超えないように前記撮影条件を調整する前項12~15のいずれかに記載の撮影条件調整方法。
(17)前記撮影条件の調整前の撮影条件と、調整後の撮影条件の少なくともいずれかの撮影条件で撮影され、前記取得ステップで取得した複数枚の撮影画像毎に、撮影画像の明るさの分布を示すヒストグラムの度数を、当該度数の大小を識別可能に表現できるパラメータによりヒストグラムの階級の方向に一次元的に表示した複数個の一次元ヒストグラムを作成する作成ステップと、
前記作成ステップにより作成された複数個の一次元ヒストグラムが並んで表示されるように表示データを出力する出力ステップと、
をさらに含む前項12~16のいずれかに記載の撮影条件調整方法。
(18)前記パラメータは色分けである前項17に記載の撮影条件調整方法。
(19)前記パラメータはグラデーションである前項17に記載の撮影条件調整方法。
(20)前記表示データは、前記一次元ヒストグラムが並んで表示される表示データである前項17~19のいずれかに記載の撮影条件調整方法。
(21)前記表示データは、中間の撮影画像が間引かれた一次元ヒストグラムが表示される表示データである前項17~20のいずれかに記載の撮影条件調整方法。
(22)間引いたフレームにおける撮影条件を、その前後にある使用フレームで求められた撮影条件から流用する前項21に記載の撮影条件調整方法。
(23)前項12~22のいずれかに記載の撮影条件調整方法をコンピュータに実行させるためのプログラム。
一般的に、画像の明るさの分布を示すには図8のようなヒストグラムが用いられる。ヒストグラムの横軸は階級であり、この実施形態では撮影画像の画素値を表す。縦軸は度数であり、この実施形態では撮影画像においてその画素値をとる画素の数である。
図8は、ヒストグラム作成部32で作成された図7の撮影画像25のヒストグラムである。図8のヒストグラムにおいて、画素値ゼロの付近の山が暗領域11、画素値50の付近の山が光帯10である。図8から理解されるように、ヒストグラムの画素値50の近傍に、光帯10に起因するピークがあり、画素値0の近傍に、暗領域11に起因するピークがある。
撮影毎に露光時間を変える場合、(9)式で示すような露光時間ExposureTime2(i)に設定する。
2 カメラ
3 データ処理装置(撮影条件調整装置)
31 画像取得部
32 ヒストグラム作成部
33 一次元ヒストグラム作成部
34 データ出力部
35 表示装置(表示体)
36 撮影条件調整部
4 プリンタ
5 一次元ヒストグラム
6 記録媒体(表示体)
10 光帯
11 暗領域
Claims (23)
- ワークに対して照明装置とカメラの少なくとも一方を相対的に移動させながら、前記照明装置で照明されたワークを前記カメラで撮影したときの複数枚の撮影画像を取得する取得手段と、
前記取得手段で取得した複数枚の撮影画像毎に、画像の明るさの分布が一様になるように、前記カメラによる撮影条件を調整する調整手段と、
を備えた撮影条件調整装置。 - 前記撮影条件には、前記カメラの露光時間が含まれる請求項1に記載の撮影条件調整装置。
- 前記撮影条件には、前記カメラのゲインが含まれる請求項1に記載の撮影条件調整装置。
- 前記調整手段は、撮影画像における暗領域の最大光量が一定値となるように、あるいは光帯の最小光量が一定値となるように、あるいは暗領域の最大光量と光帯の最小光量の中間光量が一定値となるように前記撮影条件を調整する請求項1~3のいずれかに記載の撮影条件調整装置。
- 前記調整手段は、撮影画像における光帯の最大光量が上限値を超えないように前記撮影条件を調整する請求項1~4のいずれかに記載の撮影条件調整装置。
- 前記撮影条件の調整前の撮影条件と、調整後の撮影条件の少なくともいずれかの撮影条件で撮影され、前記取得手段で取得した複数枚の撮影画像毎に、撮影画像の明るさの分布を示すヒストグラムの度数を、当該度数の大小を識別可能に表現できるパラメータによりヒストグラムの階級の方向に一次元的に表示した複数個の一次元ヒストグラムを作成する作成手段と、
前記作成手段により作成された複数個の一次元ヒストグラムが並んで表示されるように表示データを出力する出力手段と、
をさらに備えている請求項1~5のいずれかに記載の撮影条件調整装置。 - 前記パラメータは色分けである請求項6に記載の撮影条件調整装置。
- 前記パラメータはグラデーションである請求項6に記載の撮影条件調整装置。
- 前記表示データは、前記一次元ヒストグラムが並んで表示される表示データである請求項6~8のいずれかに記載の撮影条件調整装置。
- 前記表示データは、中間の撮影画像が間引かれた一次元ヒストグラムが表示される表示データである請求項6~8のいずれかに記載の撮影条件調整装置。
- 間引いたフレームにおける撮影条件を、その前後にある使用フレームで求められた撮影条件から流用する請求項10に記載の撮影条件調整装置。
- ワークに対して照明装置とカメラの少なくとも一方を相対的に移動させながら、前記照明装置で照明されたワークを前記カメラで撮影したときの複数枚の撮影画像を取得する取得ステップと、
前記取得ステップで取得した複数枚の撮影画像毎に、画像の明るさの分布が一様になるように、前記カメラによる撮影条件を調整する調整ステップと、
を含む撮影条件調整方法。 - 前記撮影条件には、前記カメラの露光時間が含まれる請求項12に記載の撮影条件調整方法。
- 前記撮影条件には、前記カメラのゲインが含まれる請求項12に記載の撮影条件調整方法。
- 前記調整ステップでは、撮影画像における暗領域の最大光量が一定値となるように、あるいは光帯の最小光量が一定値となるように、あるいは暗領域の最大光量と光帯の最小光量の中間光量が一定値となるように前記撮影条件を調整する請求項12~14のいずれかに記載の撮影条件調整方法。
- 前記調整ステップでは、撮影画像における光帯の最大光量が上限値を超えないように前記撮影条件を調整する請求項12~15のいずれかに記載の撮影条件調整方法。
- 前記撮影条件の調整前の撮影条件と、調整後の撮影条件の少なくともいずれかの撮影条件で撮影され、前記取得ステップで取得した複数枚の撮影画像毎に、撮影画像の明るさの分布を示すヒストグラムの度数を、当該度数の大小を識別可能に表現できるパラメータによりヒストグラムの階級の方向に一次元的に表示した複数個の一次元ヒストグラムを作成する作成ステップと、
前記作成ステップにより作成された複数個の一次元ヒストグラムが並んで表示されるように表示データを出力する出力ステップと、
をさらに含む請求項12~16のいずれかに記載の撮影条件調整方法。 - 前記パラメータは色分けである請求項17に記載の撮影条件調整方法。
- 前記パラメータはグラデーションである請求項17に記載の撮影条件調整方法。
- 前記表示データは、前記一次元ヒストグラムが並んで表示される表示データである請求項17~19のいずれかに記載の撮影条件調整方法。
- 前記表示データは、中間の撮影画像が間引かれた一次元ヒストグラムが表示される表示データである請求項17~20のいずれかに記載の撮影条件調整方法。
- 間引いたフレームにおける撮影条件を、その前後にある使用フレームで求められた撮影条件から流用する請求項21に記載の撮影条件調整方法。
- 請求項12~22のいずれかに記載の撮影条件調整方法をコンピュータに実行させるためのプログラム。
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JP2005024271A (ja) | 2003-06-30 | 2005-01-27 | Olympus Corp | 撮像制御方法及び基板検査装置 |
JP2009281835A (ja) | 2008-05-21 | 2009-12-03 | Dainippon Screen Mfg Co Ltd | 基板処理システム、検査装置および検査方法 |
JP2011237302A (ja) * | 2010-05-11 | 2011-11-24 | Sumco Corp | ウェーハ欠陥検査装置及びウェーハ欠陥検査方法 |
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JP2021122664A (ja) | 2020-02-07 | 2021-08-30 | サミー株式会社 | ぱちんこ遊技機 |
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JPH05164703A (ja) | 1991-12-17 | 1993-06-29 | Honda Motor Co Ltd | ワーク表面検査方法 |
JP2005024271A (ja) | 2003-06-30 | 2005-01-27 | Olympus Corp | 撮像制御方法及び基板検査装置 |
JP2009281835A (ja) | 2008-05-21 | 2009-12-03 | Dainippon Screen Mfg Co Ltd | 基板処理システム、検査装置および検査方法 |
JP2011237302A (ja) * | 2010-05-11 | 2011-11-24 | Sumco Corp | ウェーハ欠陥検査装置及びウェーハ欠陥検査方法 |
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