JP2008249430A - Two-dimensional information detecting method and its device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a two-dimensional information detecting method and its device for realizing higher speed and precision of distance image detection. <P>SOLUTION: Intensity-modulated light beams of M kinds with their phases shifted in increments of π/M (M is an integer equal to four or larger) are sequentially switched with respect to each frame and applied to a subject. When the respective light beams are applied to the subject, reflected light beams from the subject are passed through a shutter to take two-dimensional images of M kinds with respect to each frame, the shutter shifting the time of photo-storage and transfer with respect to each horizontal scanning line. Based on ratios of the sum of difference images which are differences between the two-dimensional images of M kinds to differences in the difference images, a distance image is calculated in which distance is expressed by the luminance of the image. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a three-dimensional information detection method and apparatus, and more particularly to a three-dimensional information detection method and apparatus for detecting a distance from a camera to a subject and acquiring three-dimensional information.

  As a three-dimensional information detection method for detecting a distance from a camera to a subject and acquiring three-dimensional information, for example, there are methods described in Patent Document 1 and Patent Document 2.

  The image laser radar apparatus described in Patent Document 1 has a laser light source that is intensity-modulated at a predetermined frequency and irradiates a subject with emitted light, and has a function of receiving reflected light from the subject and enhancing the image, and gain at a predetermined frequency. And an image intensifier tube in which the output of the image intensifier is turned on only in a period in which the gain monotonously increases or decreases in a period of approximately ¼ or less of the gain modulation period. By synchronizing these periods, it is possible to obtain information in which the shade changes periodically according to the distance, and the distance measurement result is obtained as a shade image.

Japanese Patent Application Laid-Open No. 2004-228667 forms three-dimensional information for forming a subject illuminated with light having a predetermined luminance as an optical image and detecting the distance between each point of the subject from an image obtained by capturing the optical image with a predetermined imaging gain. A detection method in which at least one of the predetermined luminance and imaging gain changes with time, whereby the distance of each point of the subject can be detected at a speed that follows the frame time of the video signal in real time. It is what you want to do. By using the luminance or imaging gain that changes with time, a two-dimensional luminance distribution of the image of the imaged subject is obtained, and this luminance distribution includes distance information to each point of the subject. It is possible to detect the three-dimensional information.
JP-A-6-294868 JP 2000-121339 A

  The invention described in Patent Document 1 has a problem that it is difficult to capture the three-dimensional information of the subject at the speed of the frame time of the video signal because there is a change in the two-dimensional scanning of the laser light and the modulation phase of the illumination light. is there.

  An object of the invention described in Patent Document 2 is to detect 3D information of a subject within a frame of a video signal.

  Conventionally, in a CCD (Charge Coupled Device) generally used for broadcasting and video content, the image quality transfer rate comparable to that of a TV image is limited to about 3 OHz, and further, a distance image that is three-dimensional information of a subject from a plurality of images. The effective update speed of the distance image is (CCD transfer rate) / (number of images necessary for distance calculation), and the distance image of the distance image with smooth motion at the video frame rate (about 30 Hz or 60 Hz) is calculated. Detection was difficult.

  Current CCD sensors require a transistor for each pixel, and cannot achieve both high definition and high speed. On the other hand, CMOS (Complementary Metal Oxide Semiconductor) sensors have been put into practical use in recent years, whose performance has been remarkably improved and whose manufacturing cost is low. In recent years, a CMOS sensor having a high-definition class high-definition pixel and a high-speed transfer frame rate of 60 Hz to 120 Hz or more has been developed.

  However, an image sensor using a CMOS sensor having a high-definition pixel and a high-speed transfer frame rate is a so-called rolling shutter, and accumulates and transfers signals in a time division manner for each horizontal scanning line of an image.

  The conventional three-dimensional information detection method is capable of detecting a distance image only by a full frame shutter method in which all pixels are accumulated for the same time and transferred at the same time, and is a high-definition and high-speed transfer frame rate CMOS of a rolling shutter method. The image sensor could not be used for distance image detection.

  The present invention has been made in view of the above points, and an object of the present invention is to provide a three-dimensional information detection method and apparatus for realizing high-speed and high-definition distance image detection.

In the three-dimensional information detection method according to an embodiment of the present invention, M types of intensity-modulated light whose phases are shifted by π / M (M is an integer of 4 or more) are sequentially switched for each frame, and the subject is irradiated.
M-type two-dimensional images are photographed for each frame through a shutter in which the light accumulation and transfer timing is shifted for each horizontal scanning line with respect to the reflected light from the subject when irradiating each intensity modulation,
By calculating a distance image in which the distance is represented by the luminance of the image based on the ratio of the difference image sum that is the difference between the M types of two-dimensional images and the difference between the difference images, the distance image detection is speeded up and increased. Refinement can be realized.

Further, in the three-dimensional information detection method according to another embodiment of the present invention, four types of intensity-modulated light whose phases are shifted by π / 4 are sequentially switched for each frame to irradiate the subject,
Four types of two-dimensional images are photographed for each frame through a shutter in which the timing of light accumulation and transfer is shifted for each horizontal scanning line for the reflected light from the subject when irradiating each intensity modulation,
A distance image in which the distance is represented by the luminance of the image based on a ratio of a sum of two kinds of difference images, which is a difference between two kinds of two-dimensional images whose phases are different by π / 2, and a difference between the two kinds of difference images. By calculating, it is possible to realize high speed and high definition of distance image detection.

A three-dimensional information detection apparatus according to an embodiment of the present invention includes a light source that sequentially switches M types of intensity-modulated light whose phase is shifted by π / M (M is an integer of 4 or more) and irradiates a subject.
Imaging means for capturing M types of two-dimensional images for each frame through a shutter that shifts the timing of light accumulation and transfer for each horizontal scanning line of reflected light from a subject when irradiating each intensity modulation;
A distance image calculating means for calculating a distance image representing a distance by the luminance of the image based on a ratio of a difference image sum that is a difference between the M types of two-dimensional images and a difference between the difference images; High-speed and high-definition image detection can be realized.

A three-dimensional information detection apparatus according to another embodiment of the present invention includes a light source that sequentially switches four types of intensity-modulated light whose phase is shifted by π / 4 for each frame and irradiates the subject.
Imaging means for capturing four types of two-dimensional images for each frame through a shutter in which the timing of light accumulation and transfer is shifted for each horizontal scanning line for the reflected light from the subject when irradiating each intensity modulation;
A distance representing the distance of the subject in terms of image brightness based on the ratio of the sum of two types of difference images, which is the difference between two types of two-dimensional images that differ in phase by π / 2, and the difference between the two types of difference images. By having the distance image calculating means for calculating the image, it is possible to realize speeding up and high definition of the distance image detection.

In the three-dimensional information detection apparatus,
The intensity modulated light may be a sine wave.

In the three-dimensional information detection apparatus,
The distance image calculation means may be configured to change a coefficient value used for calculation of the distance image in accordance with a shift in light accumulation and transfer timing for each horizontal scanning line.

In the three-dimensional information detection apparatus,
A dividing unit that divides the reflected light from the subject into a distance image and a color image;
And a color photographing means for photographing a color image with the light from the dividing means.

  According to the present invention, high-speed and high-definition distance image detection can be realized.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 shows a block diagram of an embodiment of the three-dimensional information detection apparatus of the present invention. In the figure, the three-dimensional information detection apparatus has a light source unit 3 that irradiates a subject 2 with intensity-modulated light and a camera lens 4 that captures an image. Further, the optical system has a splitting optical system 6 that splits the received reflected light for distance image shooting and color image shooting.

  The distance detection unit 7 that detects a distance image includes an imaging unit 8 such as an image intensifier, and a two-dimensional image sensor 9 that has a rolling shutter as a high-speed shutter and images the output of the imaging unit 8. The two-dimensional image sensor 9 uses, for example, a CMOS sensor that performs high-speed storage and transfer for each horizontal scanning line.

  Image signals output from the two-dimensional image sensor 9 are recorded in a plurality of memories 10. An image signal is read from the plurality of memories 10 and supplied to the image signal processing device 11 to calculate a distance image.

  A new image signal is sequentially overwritten in the plurality of memories 10, and each time the image signal processing device 11 performs an operation for calculating the depth distance dd as a distance image by the equation (1), and the distance image is output as a moving image. Is done.

ここで、Ｖ_１，Ｖ_２，Ｖ_３，Ｖ_４は強度変調光の位相をπ／２ずつ変化させて撮影した映像信号、ｋは定数、ｈは画像の水平走査ライン毎に値が変化する係数である。この（１）式については後述する。

Here, V ₁ , V ₂ , V ₃ , and V ₄ are video signals captured by changing the phase of the intensity-modulated light by π / 2, k is a constant, and h is a value that changes for each horizontal scanning line of the image. It is a coefficient. This equation (1) will be described later.

  The intensity-modulated light output from the light source unit 3 and the high-speed shutter of the imaging unit 8 are driven in synchronization with the shutter trigger signal output from the signal generator 13. Further, the phase switcher 14 performs switching control of the phase of the modulation signal for each video frame on the basis of the vertical synchronization signal which is a video reference.

  Further, a normal color image is taken by a color camera 15 provided after the dividing optical system 6. The color image obtained here is output after being delayed by a delay circuit 16 corresponding to the distance calculation time.

As shown in FIGS. 2A to 2D, the light source unit 3 includes a first intensity-modulated light pattern 20 and a second intensity in which the phase of light that is intensity-modulated in a sine wave is changed by π / 2. The modulated light pattern 21, the third intensity modulated light pattern 22, and the fourth intensity modulated light pattern 23 are output. As shown in FIGS. 2A to 2D, the imaging unit 8 performs the shutter photographing 24 at a fixed timing and time width, and performs the first video signal V ₁ , the second video signal V ₂ , and the third video signal V 3. Video signal V ₃ and fourth video signal V ₄ are acquired.

  The timing of the phase change is performed in synchronization with the frame rate of the image, and the time width of shutter shooting is set to a time sufficiently shorter than the light intensity modulation period, and the signal is taken in.

  When a CMOS sensor capable of high-speed transfer with high-definition pixels is used as the two-dimensional image sensor 9, the timing of light accumulation and transfer is shifted for each horizontal scanning line as shown in FIG.

  In FIG. 3, the horizontal axis indicates time, the top of the vertical axis indicates the first horizontal scanning line at the top of the image, and the total number of horizontal scanning lines of the CMOS sensor is N. At this time, shooting is performed by switching the first intensity modulated light, the second intensity modulated light, the third intensity modulated light, and the fourth intensity modulated light for each frame time.

  In the CMOS sensor, since the accumulation time and transfer timing of the optical signal are shifted for each horizontal scanning line, the accumulation ratio of the first intensity modulated light and the second intensity modulated light in the first frame is different for each horizontal scanning line. Is different. Here, the accumulation ratio of the first intensity-modulated light and the second intensity-modulated light in the nth horizontal scanning line in the first frame accumulation period is expressed by equation (2).

h (n): 1-h (n) (2)
The method for obtaining the distance image in this case is shown below using an equation. As shown in FIG. 2, the phase of the intensity modulated light is shifted by π / 2 for each frame, and images from the first frame to the fourth frame are sequentially taken. Image intensities (image luminances) y _{1 to} y ₄ photographed in each of the four-pole intensity-modulated light patterns are expressed by the following equations (3) to (7).

ただし、σは被写体の反射率、φは変調位相、ｅは光源以外の外光成分、ｔ_０はシャッタタイミング、νは光速度、ｆは強度変調の周波数、ｄはカメラ（撮像部８）から被写体２までの距離である。なお、（３）〜（６）式における係数「１／２」，定数「１」は画像強度の値を「０」〜「１」の範囲に規格化するために導入している。

Where σ is the reflectance of the object, φ is the modulation phase, e is the external light component other than the light source, t ₀ is the shutter timing, ν is the speed of light, f is the frequency of intensity modulation, and d is from the camera (imaging unit 8). This is the distance to the subject 2. It should be noted that the coefficient “1/2” and the constant “1” in the equations (3) to (6) are introduced in order to normalize the value of the image intensity in the range of “0” to “1”.

Here, when the two-dimensional image sensor 9 uses a rolling shutter having different accumulation and transfer timings for each horizontal scanning line as shown in FIG. 3, the accumulation time for acquiring one image in the nth horizontal scanning line. If the light switching timing ratio is h: (1-h), the image intensities of the first to fourth video signals V _{1 to} V ₄ obtained in the first to fourth frames are (8) to It is expressed by equation (11).

上記の（８）〜（１１）式より、（１２），（１３）式が導かれ、（１２），（１３）式から（１４），（１５）式が導かれる。更に、（１４），（１５）式から位相φを表す（１６）式が得られる。ここで、（７）式の関係があるため、（１６）式から距離ｄを表す（１７）式が得られる。

Equations (12) and (13) are derived from the above equations (8) to (11), and equations (14) and (15) are derived from equations (12) and (13). Furthermore, the equation (16) representing the phase φ is obtained from the equations (14) and (15). Here, since there is a relationship of Expression (7), Expression (17) representing the distance d is obtained from Expression (16).

ところで、（１７）式の右辺第１項は、図４に示すようにカメラ（撮像部８）から測定レンジ（測定可能な範囲）ＭＲまでの距離Ｌ１を表しており、右辺第２項は、測定レンジＭＲ内での被写体２の奥行き距離Ｌ２を表している。実際の撮影ではシャッタタイミングｔ_０を調整することで距離Ｌ１を調整し、被写体２が測定レンジＭＲ内に存在するように設定する。

By the way, the first term on the right side of the equation (17) represents the distance L1 from the camera (imaging unit 8) to the measurement range (measurable range) MR, as shown in FIG. The depth distance L2 of the subject 2 within the measurement range MR is shown. In actual shooting by adjusting the distance L1 by adjusting the shutter timing t _0, set so that the subject 2 exists in the measurement range MR.

  Here, since the depth distance of the subject to be obtained, that is, the three-dimensional information, is the second term on the right side of Expression (17), the depth distance dd is expressed by Expression (1) by setting ν / 4πf = k. The

  As is clear from the equations (17) and (1), the distance d and the depth distance dd between the subjects can be obtained from the camera by removing the influence of the reflectance σ of the subject and the influence of the external light component e.

  In this manner, it is possible to perform distance image detection using a rolling shutter type high-definition and high-speed transfer frame rate CMOS image sensor.

Here, the coefficient h is a function h (n) of a horizontal scanning line number that is different for each horizontal scanning line, and is monotonically from the initial value h _{0 for} each horizontal scanning line as represented by the following equation. Is given in increments Δh.

h (n) = h ₀ + n × Δh (18)
By the way, in the equation (1), the constant k (= ν / 4πf) can be variably adjusted to widen the dynamic range of the video signal level, and the measurement resolution and measurement range of the distance image can be expanded. For example, when the video signal level is 0 to 100%, if k is small, the depth distance is expressed with a video signal level of 30 to 70%, for example. By increasing k, for example, the distance can be expressed using a video signal level of 10 to 90%. That is, the number of gradations expressing the distance increases, and the distance can be expressed more finely and the resolution is improved.

  In addition, the measurement range is increased by increasing the light modulation period, but generally the distance detection resolution is lowered. Increasing k can compensate for the decrease in distance detection resolution, so indirectly increasing k is effective in expanding the measurement range.

  In equations (1) and (17), a rounding error occurs due to the division process. However, the calculation process is performed with an accuracy corresponding to the number of gradation bits of the output video signal of the camera, and the influence of the rounding error is affected. Minimized and accurate distance detection can be performed.

The distance detection unit 7 obtains the first to fourth video signals V _{1 to} V ₄ for each frame, writes them in the plurality of memories 10, sequentially performs the arithmetic processing represented by the formula (1), and performs the distance image. Is output.

  The operation of the distance detection unit 7 will be described with reference to the flowchart shown in FIG. In step S1, a modulation signal of the light source unit 3 having an arbitrary phase is set, and in step S2, intensity-modulated light is irradiated to the subject 2.

First video signal _{V 1} is acquired in step S3. In step S 4, the first video signal V ₁ is written into the memory M ₁ in the memory 10. In the next frame, the modulation signal of the light source section 3 in step S5 is shifted by a phase [pi / 2, are similarly acquired second video signal V ₂ is written into the memory M ₂ in the memory 10. Similarly, in the next frame, the modulation signal of the light source unit 3 is shifted by the phase π / 2, and the third video signal V ₃ is acquired and written in the memory M ₃ in the memory 10. Similarly, in the next frame, the modulation signal of the light source unit 3 is shifted by the phase π / 2, and the fourth video signal V ₄ is acquired and written in the memory M ₄ in the memory 10. Further, in the next frame, the modulation signal of the light source unit 3 is shifted by the phase π / 2, and the first video signal V ₁ is acquired again and written in M ₁ in the memory 10.

As described above, the imaging cycles of the video signals V _{1 to} V ₄ are sequentially repeated. In this cycle, every time the stored contents of the memories M _{1 to} M ₄ are rewritten, the calculation of the expression (1) is performed in step S6, and the distance image is output in step S7.

  Thereby, the distance image is updated for each frame, and the distance image of the moving subject can be captured.

  FIG. 6 shows a configuration diagram of an embodiment of the phase switch 14. In the figure, the signal generator 13 outputs a sinusoidal modulation signal. When the depth range of the subject to be photographed is approximately 1.5 m to 7.5 m, the frequency of the modulation signal can be 10 MHz to 50 MHz.

  The phase switcher 14 distributes the modulation signal from the signal generator 13 into four, and the phase shifter 51 shifts the phase of the modulation signal φ, φ + π / 4, φ + π / 2, φ + 3π / 4 by π / 2, respectively. To the switch 53. The switch 53 is supplied with a video vertical synchronizing signal from the terminal 52, and the phase of the modulation signal is switched by the switch 53 for each frame and is output from the terminal 54. A shutter trigger signal for driving the high-speed shutter of the two-dimensional image sensor 9 is also distributed from the signal generator 13 and output from the terminal 55.

  The detection of the distance image can be performed simultaneously with the color image photographing, and the subject is irradiated with a light source for detecting distance (light source unit 3) and the subject is illuminated under normal illumination. For example, illumination is performed with a light source having a visible light component to capture a color image, and the wavelength of the light source for distance detection is crossed by using a near-infrared wavelength region that is not used for capturing a color image. The influence of talk can be reduced.

  However, as shown by the equation (17), in the method of the present invention, since the distance can be obtained by canceling the disturbance light, the distance can be detected even under the external light having the same wavelength as the distance detection wavelength. is there.

  In the photographing optical system, a zoom camera lens is used, and the image is divided into two by the dividing optical system 6 in the middle of the image formation, or divided into wavelengths for light for color image and light with distance detection. Thereby, the zoom function of the camera lens can be used. Specifically, a precision focus lens configuration in which a half mirror is inserted in the middle of the zoom camera lens, a lens is attached to the end of the zoom camera lens, and divided images are formed, and a focus / defocus sensor is placed on the imaging surface to perform focus detection. An optical system can be used, and thereby miniaturization can be realized.

  However, when photographing a color image and a distance image, in the device of the present invention, since the imaging unit 8 and the color camera 15 are not fixed by an optical block such as a prism, the color image and the distance image are displayed when the lens is attached. There may be a shift in pixel units. This deviation can be absorbed by introducing a mechanical stage using a micrometer or a stepping motor.

  In order to align frames with a color image and a distance image, the timing of the color image and the distance image can be made the same by delaying the color image by the delay circuit 16.

Further, when the frame rate of the color image is, for example, 30 Hz, the frame rate for acquiring the video signals V _{1 to} V ₄ for the distance image is repeatedly photographed at 120 Hz, which is four times the frame rate of the color image. Thereby, the update time of a color image and a distance image can be made to correspond.

  In addition, because the wavelength of the light source for distance detection and the light source for color image shooting are different, if the angle of view of the distance image and the color image is different due to the characteristics of the lens, image processing for geometric shape correction for the distance image To adjust the angle of view of both.

In particular, when an image is taken with an image intensifier, noise is mixed into the distance image due to the influence of shot noise. These noise components cause a decrease in distance detection accuracy. These noise components can be removed with an electrical filter. For example, random noise can be reduced by performing recursive filtering or median filtering on the stored contents of the memories M _{1 to} M ₄ .

Further, in the method of the present invention, the distance is calculated based on the video signals V _{1 to} V ₄ of 4 frames, which is twice as large as the conventional method of detecting the distance between two images, and from the phase of the sine wave. The distance is detected. In the image calculation, the SN ratio is improved by the square root of the number of images. Therefore, the method of the present invention can be expected to improve the accuracy of distance detection by 1.41 times as compared with the conventional method, and the distance strong against external noise. Detection is possible.

  Further, even if the modulation signal supplied to the light source unit 3 is a distorted waveform shifted from a sine wave, if the waveform is measured in advance, the detection value of the distance finally obtained is corrected, The correct distance value can be corrected. Furthermore, although the above embodiment has been described as a sinusoidal intensity-modulated light, the intensity of the intensity-modulated light that monotonously increases and decreases in the same waveform with a single cycle, if the waveform shape is known, A distance image can be detected by performing signal processing with the same raw material.

  In the conventional method, modulated images that increase or decrease in a triangular wave shape are irradiated, and a distance image is obtained by two imaging operations. For this reason, the measurement of the subject at the end of the measurement range calculates the distance from the captured image when the light starts to increase or decrease. Therefore, the distance is calculated based on the image having a low luminance level and a poor SN ratio. As a result, the resolution becomes worse at the end of the measurement range.

  On the other hand, in the method of the present invention, four images shifted by π / 2 phase are photographed to obtain a distance image, so that an image having a substantially constant luminance level can be obtained by averaging. That is, since the distance is not calculated only from an image having an extremely low luminance level, good performance can be obtained over the entire measurement range.

  According to the method of the present invention, the distance image can be acquired simultaneously with the acquisition of the color image, so that even during the live broadcast, for example, only the person near the camera is extracted and the screen is cut out and the screen synthesis is performed in real time. It becomes possible.

  In addition, this makes it possible to extract only images of subjects within a predetermined distance range from the camera, which was not possible with the conventional chroma key method using a blue background, and it was difficult to synthesize computer graphics and live-action images. Can be realized. Furthermore, since the device of the present invention has a high-speed three-dimensional shape measurement function, it can be utilized in a wide range of industrial fields.

  In the above embodiment, the imaging unit 8 is used as an example of the imaging unit, the image signal processing device 11 is used as an example of the distance image calculating unit, the dividing optical system 6 is used as an example of the dividing unit, and an example of the color imaging unit. A color camera 15 is used.

It is a block of one Embodiment of the three-dimensional information detection apparatus of this invention. It is a figure for demonstrating an intensity | strength modulation light pattern and the timing of shutter imaging | photography. It is a figure for demonstrating the optical accumulation and transfer timing of a CMOS sensor. It is a figure for demonstrating a measurement range and depth distance. It is a flowchart for operation | movement description of a distance detection part. It is a block diagram of one Embodiment of a phase switch.

Explanation of symbols

DESCRIPTION OF SYMBOLS 2 Subject 3 Light source part 4 Camera lens 6 Division | segmentation optical system 7 Distance detection part 8 Imaging part 9 Two-dimensional image sensor 10 Memory 11 Image signal processing apparatus 13 Signal generator 14 Phase switch 15 Color camera 16 Delay circuit 51 Phase shifter 53 Switch

Claims (7)

M types of intensity-modulated light whose phase is shifted by π / M (M is an integer of 4 or more) are sequentially switched for each frame to irradiate the subject.
M-type two-dimensional images are photographed for each frame through a shutter in which the light accumulation and transfer timing is shifted for each horizontal scanning line with respect to the reflected light from the subject when irradiating each intensity modulation,
3. A three-dimensional information detection method, comprising: calculating a distance image that represents a distance as a luminance of an image based on a ratio between a difference image sum that is a difference between the M types of two-dimensional images and a difference between the difference images. Four types of intensity-modulated light whose phase is shifted by π / 4 are sequentially switched for each frame to irradiate the subject.
Four types of two-dimensional images are photographed for each frame through a shutter in which the timing of light accumulation and transfer is shifted for each horizontal scanning line for the reflected light from the subject when irradiating each intensity modulation,
A distance image in which the distance is represented by the luminance of the image based on a ratio of a sum of two kinds of difference images, which is a difference between two kinds of two-dimensional images whose phases are different by π / 2, and a difference between the two kinds of difference images. A three-dimensional information detection method characterized by calculating. A light source for sequentially switching M types of intensity-modulated light whose phase is shifted by π / M (M is an integer of 4 or more) for each frame and irradiating the subject;
Imaging means for capturing M types of two-dimensional images for each frame through a shutter that shifts the timing of light accumulation and transfer for each horizontal scanning line of reflected light from a subject when irradiating each intensity modulation;
A distance image calculating means for calculating a distance image representing a distance as a luminance of the image based on a ratio of a difference image sum which is a difference between the M types of two-dimensional images and a difference between the difference images. 3D information detecting device. A light source for sequentially irradiating a subject with four types of intensity-modulated light whose phase is shifted by π / 4 for each frame;
Imaging means for capturing four types of two-dimensional images for each frame through a shutter in which the timing of light accumulation and transfer is shifted for each horizontal scanning line for the reflected light from the subject when irradiating each intensity modulation;
A distance representing the distance of the subject in terms of image brightness based on the ratio of the sum of two types of difference images, which is the difference between two types of two-dimensional images that differ in phase by π / 2, and the difference between the two types of difference images. A three-dimensional information detection device comprising distance image calculation means for calculating an image. The three-dimensional information detection apparatus according to claim 4,
The three-dimensional information detection apparatus, wherein the intensity-modulated light is a sine wave. The three-dimensional information detection apparatus according to claim 4 or 5,
The three-dimensional information detection apparatus, wherein the distance image calculation unit changes a coefficient value used for calculation of the distance image in accordance with a shift in light accumulation and transfer timing for each horizontal scanning line. The three-dimensional information detection apparatus according to any one of claims 4 to 6,
A dividing unit that divides the reflected light from the subject into a distance image and a color image;
A three-dimensional information detecting apparatus comprising: color photographing means for photographing a color image with light from the dividing means.

Images