JP5862034B2 - Image display device - Google Patents

Description

  The present invention relates to an image display device.

  There has been proposed an image display device that includes a camera in an outer frame portion of a display screen and that can perform a motion operation according to the movement of a user's hand (for example, Patent Document 1).

JP 2010-81466 A

  However, in the prior art, the camera includes not only the user's hand but also the background behind the user, so there is a possibility of misdetecting other than the user's hand movement. There is a high possibility of false detection.

  An object of the present invention is to improve the detection accuracy of a motion operation by a user.

The image display device according to the present invention includes a display unit, the imaging optical system arranged in the display unit such that a normal line orthogonal to a part of the display surface of the display unit and an optical axis of the imaging optical system intersect with each other. An illuminating unit that emits the illuminating light disposed in the display unit such that a normal line orthogonal to a part of the display surface of the display unit intersects with the illuminating light, and the imaging unit. A support unit for supporting, and an adjustment unit that automatically adjusts the support unit so that a normal line orthogonal to a part of the display surface of the display unit and the optical axis of the imaging optical system intersect. It is characterized by.

  According to the present invention, it is possible to improve the detection accuracy of a motion operation by a user.

It is a side view which shows typically the digital photo frame of embodiment of this invention, and the user who operates this. It is a front view of the digital photo frame of the embodiment of the present invention. It is a block diagram which shows the structure of the control part of the digital photo frame of embodiment of this invention. It is a flowchart figure which shows the process of the control part of the digital photo frame of embodiment of this invention. It is a side view which shows the 1st modification of the digital photo frame of embodiment of this invention. It is a side view which shows the 1st modification of the digital photo frame of embodiment of this invention. It is a side view which shows the 2nd modification of the digital photo frame of embodiment of this invention. It is a side view which shows the 2nd modification of the digital photo frame of embodiment of this invention. It is a side view which shows the digital photo frame of other embodiment of this invention. It is a side view which shows the 1st modification of the digital photo frame of other embodiment of this invention. It is a side view which shows the 2nd modification of the digital photo frame of other embodiment of this invention. It is a side view which shows the 3rd modification of the digital photo frame of other embodiment of this invention. It is a figure which shows the light emission timing and light intensity change of the infrared light in the 1st object detection process of embodiment of this invention. It is a figure for demonstrating the 1st object detection process of embodiment of this invention. It is a figure which shows the light emission timing and light intensity change of the infrared light in the 2nd object detection process of embodiment of this invention. It is a figure for demonstrating the 2nd object detection process of embodiment of this invention. It is a figure which shows the light emission timing and light intensity change of the infrared light in the 3rd object detection process of embodiment of this invention. It is a figure for demonstrating the 3rd object detection process of embodiment of this invention. It is a figure which shows the light emission timing and light intensity change of the infrared light in the 4th object detection process of embodiment of this invention. It is a figure for demonstrating the 4th object detection process of embodiment of this invention.

  Hereinafter, an embodiment of the present invention will be described by taking a digital photo frame as an example of an image display device to which the present invention is applied. First, FIG. 1 and FIG. 2 will be referred to. The digital photo frame 1 of the present embodiment is generally configured by including a display 2 having a substantially rectangular display screen 2a and a camera 3 as a photographing unit. As the display 2, for example, a liquid crystal panel can be used.

  Although not shown, the camera 3 includes an image sensor such as a CCD that captures an image of a subject and a lens that forms an image of the subject on an image formation surface of the image sensor. In this embodiment, the camera 3 is integrally fixed to the front side of the display 2 and substantially at the center of the lower side of a frame (frame member) disposed on the outer periphery of the display screen 2a. The user 7 is photographed mainly with the hand 7a facing the photo frame 1 as a subject. The camera 3 is placed outside the display screen 2a so that the direction of the optical axis A (directing direction) is oblique to the direction of the normal line passing through the display screen 2a on the front (front) side of the display screen 2a. Is arranged. Here, the angle formed between the optical axis A of the camera 3 and the normal B passing through the center (or the vicinity thereof) of the display screen 2a is θa, and the angle formed between the display screen 2a and the normal D of the installation surface 6a is θb. In the range of θb = 0 ° to 40 °, θa + θb = 70 ° ± 10 °, in the range of θb = 40 ° to 60 °, θa = 30 ° ± 10 °, and in the range of θb = 60 ° to 90 °, θa + θb = 90 It is preferable to set the angle to be ± 10 °.

  In the present embodiment, an LED 4 that emits infrared light as illumination light when photographing with the camera 3 is provided adjacent to the camera 3. The LED 4 is fixed to the frame 2b so that the direction of the optical axis (the direction of the principal ray) substantially coincides with the direction of the optical axis A of the camera 3 (that is, substantially parallel). However, as described later, the direction of the optical axis of the LED 4 may be set to a direction different from the direction of the optical axis A of the camera 3. The LED 4 does not emit infrared light but may emit visible light.

  A stand 5 as a display support member for installing the display 2 on an installation surface (upper surface of the table 6) 6a is rotatably attached to the back side of the display 2. The tilt angle of the display screen 2a with respect to the installation surface 6a can be changed by rotating the stand 5 in the opening direction or the closing direction with respect to the back surface of the display 2 and setting the stand 5 to an arbitrary angle within a predetermined angle range. it can.

  The digital photo frame 1 is installed on the installation surface 6a in a predetermined posture by placing the lower side of the frame 2b and the lower end of the stand 5 in contact with the installation surface 6a. In the present embodiment, since the camera 3 and the LED 4 are fixed to the frame 2b, when the inclination angle of the display screen 2a with respect to the installation surface 6a is changed by adjusting the angle of the stand 5, the response is made accordingly. The angles of the optical axis A of the camera 3 and the optical axis C of the LED 4 with respect to the installation surface 6a are also changed. In addition, even if the inclination angle with respect to the installation surface 6a of the display screen 2a is changed, the angle θa with respect to the normal B passing through the center of the display screen 2a of the optical axis A of the camera 3 and the optical axis C of the LED 4 does not change.

  As shown in FIG. 3, the digital photo frame 1 includes a control device 11 that controls the display 2, the camera 3, and the LED 4, and an operation member 12, a connection IF 13, and a storage medium 14 are connected to the control device 11. Has been.

  The control device 11 includes a CPU, a memory, and other peripheral circuits, and controls the entire digital photo frame 1. In addition, the memory which comprises the control apparatus 11 is volatile memories, such as SDRAM, for example. This memory includes a work memory for the CPU to expand the program when the program is executed, and a buffer memory for temporarily recording data.

  The control device 11 generates image data based on an image signal output from an image sensor included in the camera 3. In addition, the control device 11 controls the lighting or lighting (light emission) intensity of the LED 4 or the extinguishing of the LED 4 when photographing with the camera 3.

  The operation member 12 includes operation buttons and the like operated by the user 7 of the digital photo frame 1. The connection IF 13 is an interface for connecting the digital photo frame 1 and an external device. In the present embodiment, the digital photo frame 1 is connected to an external device, such as a digital camera, in which image data is recorded, via the connection IF 13. Then, the control device 11 takes in the image data from the external device via the connection IF 13 and records it in the storage medium 14. As the connection IF 13, a USB interface for connecting an external device and the digital photo frame 1 by wire, a wireless LAN module for wireless connection, or the like is used. Alternatively, a memory card slot may be provided instead of the connection IF 13, and the image data may be captured by inserting a memory card in which image data is recorded in the memory card slot.

  The storage medium 14 is a non-volatile memory such as a flash memory, and stores a program executed by the control device 11 and image data captured via the connection IF 13.

  In the digital photo frame 1 in the present embodiment, the control device 11 detects the position of the hand 7a of the user 7 and a change in position between frames based on the image taken by the camera 3, and according to the detection result. The playback state of the display image 2a on the display 2 is changed. Examples of the change in the reproduction state include sending an image (changing the currently displayed image to an image to be displayed next) or returning (changing the currently displayed image to the image displayed immediately before). it can. Hereinafter, the process of changing the reproduction state of the image according to the change of the position of the hand 7a of the user 7 and the position between frames by the control device 11 will be described.

  FIG. 4 is a flowchart showing the flow of processing for changing the reproduction state of an image in accordance with the change in the position of the hand 7a of the user 7 and the position between frames. The process shown in FIG. 4 is executed by the control device 11 as a program that is activated when image reproduction / display on the display 2 is started.

  In step S <b> 1, the control device 11 starts capturing an image with the camera 3. Here, the camera 3 performs shooting at a predetermined frame rate (for example, 30 fps), and the control device 11 continuously inputs image data from the camera 3 at predetermined time intervals corresponding to the frame rate. Shall be processed. Moreover, LED4 shall not be lighted. However, the control device 11 turns on the LED 4 to capture an image for one frame, then turns off the LED 4 to capture an image for one frame, performs a difference calculation of these images, and corresponds to the difference. Image data related to the image to be processed (difference image) may be processed. By processing such a difference image, it is possible to reduce the influence of disturbance that occurs in the background in the captured image. A process (object detection process) for increasing the detection accuracy of the target object by controlling the lighting of the LED 4 and the like will be described later. Then, it progresses to step S2.

  In step S <b> 2, whether the control device 11 has detected the hand 7 a of the user 7 in the image based on the image data input from the camera 3 (image data related to the difference image when the difference calculation is performed). Judge whether or not. For example, an image of the hand 7a of the user 7 is recorded in advance as a template image, and the control device 11 matches the target image with the template image, thereby determining whether the hand 7a of the user 7 is reflected in the target image. If it is reflected, the position of the hand 7a is detected. In step S2, the control device 11 proceeds to step S3 when the position of the hand 7a is detected (in the case of Yes), and proceeds to step S5 when the hand 7a is not detected (in the case of No).

  In step S <b> 3, the control device 11 performs the operation in the image between the image data input in time series from the camera 3 (image data related to the difference image calculated in time series when the difference calculation is performed). The movement of the hand 7a of the user 7 is detected by monitoring the change in the position of 7a. If the movement of the hand 7a of the user 7 is not detected in step S3 (No), the process proceeds to step S5. On the other hand, when the movement of the hand 7a of the user 7 is detected in step S3 (in the case of Yes), the process proceeds to step S4.

  In step S4, the control device 11 changes the reproduced image according to the movement of the hand 7a. That is, when it is detected that the hand 7a has moved from the right to the left, the control device 11 determines that the image feed is instructed by the user 7, and the image currently displayed on the display 2 is moved to the left. The image is moved and displayed to be discharged from the left side of the screen, and the next image to be displayed is displayed to be introduced into the screen from the right side of the screen, and the next image to be displayed is displayed on the display 2. Display.

  On the contrary, when it is detected that the hand 7a has moved from the left to the right, the control device 11 determines that the user 7 has instructed to return the image, and displays the image currently displayed on the display 2. The image is displayed so that it moves rightward and is ejected from the right side of the screen to the outside of the screen, and the image displayed immediately before is displayed so as to be introduced into the screen from the left side of the screen. Display above.

  Here, the image is forwarded or returned in accordance with the left / right movement of the hand 7a of the user 7, but other movements may be detected to perform other processing. For example, a cursor of a predetermined shape is displayed on the screen corresponding to the position of the hand 7a of the user 7, and the cursor is moved in the screen according to the movement of the hand 7a, and the instruction input is displayed on the screen. The icon or the like may be selected. Further, for example, the display magnification of the image may be changed by detecting the vertical movement of the hand 7a.

  Thereafter, in step S5, the control device 11 determines whether or not the user 7 has instructed to end the reproduction of the image. If termination is not instructed in step S5 (in the case of No), the process returns to step S2, and if termination is instructed (in the case of Yes), this process is terminated.

  According to the present embodiment described above, the direction of the optical axis A of the camera 3 is normal to the direction passing through the display screen 2a (in this embodiment, the normal B passing through the center of the display screen 2a as an example). The front side of the display screen 2a is arranged outside the display screen 2a so as to cross at, for example, about 30 °. Thereby, the detection range of the hand 7a which performs the motion operation of the user 7 can be limited to the vicinity of the apparatus. That is, the hand 7a that performs the motion operation of the user 7 or the vicinity thereof enters the field of view of the camera 3, but the background behind the user 7 can be prevented from entering, so that, for example, another person crosses the back of the user 7. Even in this case, it is possible to prevent erroneous detection due to detection of a part of the other person without entering the shooting range.

  Next, a first modification of the digital photo frame 1 described above will be described with reference to FIGS. Components substantially the same as those in FIGS. 1 to 3 are denoted by the same reference numerals, and the description thereof is omitted. That is, in the above-described embodiment, the camera 3 has been described as being fixed to the substantially central portion of the lower side portion of the frame 2b of the display 2. Therefore, when the inclination of the display screen 2a is changed by changing the angle of the stand 5, the orientation direction of the camera 3 is also changed accordingly.

  On the other hand, in the first modified example, the orientation of the camera 3 is not changed even when the inclination of the display screen 2a is changed by changing the angle of the stand 5 as the display support member. Yes. That is, the camera 3 is fixed to the camera support member 8, and the camera support member 8 is rotatably supported near the lower side of the frame 2b via a rotation shaft 8a set in a direction substantially parallel to the lower side. . Further, the camera support member 8 has a certain amount of offset load that directs the camera 3 in a substantially constant direction by the action of gravity in a state where the digital photo frame 1 is lifted, and its lower surface is formed flat. The contact surface 8b is made. When the digital photo frame 1 is installed on the installation surface 6a, the contact surface 8b of the camera support member 8 contacts the installation surface 6a, the rotation of the camera support member 8 is restricted, and the camera 3 is directed in a certain direction. It is like that. Thereby, for example, even if the inclination of the display 2 is changed so that the state shown in FIG. 5 is changed to the state shown in FIG. 6, the directing direction of the camera 3 (direction of the optical axis A) is not changed, Will do.

  Even when the LED 4 is fixed to the camera support member 8 and the tilt of the display 2 is changed, the direction of the LED 4 (the direction of the optical axis) is the same as the direction of the camera 3 (the direction of the optical axis A). You may make it point to a fixed direction.

  Next, a second modification of the digital photo frame 1 described above will be described with reference to FIGS. Components substantially the same as those in FIGS. 1 to 3 are denoted by the same reference numerals, and the description thereof is omitted. That is, the second modified example is configured such that the directivity direction of the camera 3 is not changed even when the inclination of the display screen 2a is changed, similarly to the first modified example described above. That is, in the second modification, a pedestal 9 as a display support member is provided in place of the stand 5, and is rotatably supported on the pedestal 9 via the display 2 and the rotation shaft 9a. The rotation of the display 2 is subjected to resistance to the extent that the supporting portion with respect to the pedestal 9 can maintain its own posture, and the posture can be changed by the user 7 pressing with the hand, but the posture is maintained in a state where the pressing is not performed. It has become. The camera 3 is fixed to the base 9 in a predetermined direction. Thereby, for example, even if the inclination of the display 2 is changed so that the state shown in FIG. 7 is changed to the state shown in FIG. 8, the directivity direction (direction of the optical axis A) of the camera 3 is not changed, Will do.

  Even when the LED 4 is fixed to the base 9 in a predetermined direction and fixed, and the tilt of the display 2 is changed, the directivity direction of the LED 4 (direction of the optical axis C) is the same as the orientation direction of the camera 3 (the optical axis A). As in the case of (direction), a certain direction may be directed.

  Next, as another embodiment of the present invention, the arrangement of the LEDs 4 will be described in detail. For example, as shown in FIG. 9, the LED 4 is integrally fixed to a substantially central portion of a lower side portion of a frame (frame member) disposed on the outer periphery of the display screen 2 a on the front side of the display 2. The optical axis C is disposed outside the display screen 2a so that the direction (directing direction) of the optical axis C is oblique to the direction of the normal B passing through the display screen 2a on the front (front) side of the display screen 2a. You can

  The angle θ2 of the optical axis C of the LED 4 with respect to the normal B passing through the center (or the vicinity thereof) of the display screen 2a is set to be within a range of θ2 = 40 ° ± 20 °, for example. The angle θ2 is appropriately set according to the size of the display screen 2a of the display 2, and the angle θ2 is more preferably about θ2 = 40 ° ± 10 °, and most preferably about θ2 = 40 °.

  In this way, by arranging the LED 4 so that the direction of the optical axis C is oblique to the normal B passing through the display screen 2a, the hand 7a that performs the motion operation of the user 7 as the detection target object. Is illuminated by the illumination light from the LED 4, but the body of the user other than the hand 7a and the background behind it are not illuminated, and in the captured image, the hand 7a as the target object is bright and the remaining part is dark. Therefore, the detection accuracy of the hand 7a can be improved by setting an appropriate threshold value.

  In FIG. 9, the camera 3 is fixed to the approximate center of the upper side of the frame arranged on the outer periphery of the display screen 2a. However, as shown in FIG. 10, the side of the frame (left side or right side). You may fix to the approximate center part. Although not shown in FIG. 9, the positions of the camera 3 and the LED 4 may be reversed, that is, the LED 4 may be disposed at the position of the camera 3 and the camera 3 may be disposed at the position of the LED 4. In these cases, the direction of the optical axis A of the camera 3 may be substantially parallel to the normal B passing through the display screen 2a, or may be obliquely crossed as described above. .

  When the direction of the optical axis A of the camera 3 and the direction of the optical axis C of the LED 4 are oblique to the normal B passing through the display screen 2a, for example, as shown in FIG. 3 and LED 4 are arranged adjacent to each other at substantially the center of the lower side of the frame constituting the outer periphery of the display screen 2a, the angle θa of the optical axis A of the camera 3 with respect to the normal B passing through the display screen 2a and the light of the LED 4 The angle θ2 of the axis C with respect to the normal B may be set to be substantially equal. By doing so, the detection accuracy is improved by making the optical axis A of the camera 3 obliquely intersect the normal B, and the optical axis C of the LED 4 is obliquely intersected by the normal B. It is possible to synergistically realize the effect of improving the detection accuracy.

  As shown in FIG. 12, the camera 3 and the LED 4 are arranged, and the angle θa with respect to the normal B passing through the display screen 2a of the optical axis A of the camera 3 and the angle of the optical axis C of the LED 4 with respect to the normal B Even if θ2 is set substantially equal, it is effective as well.

  Further, when both the direction of the optical axis A of the camera 3 and the direction of the optical axis C of the LED 4 are oblique to the normal B passing through the display screen 2a, the display screen of the optical axis A of the camera 3 is displayed. When the angle θa with respect to the normal B passing through 2a and the angle θ2 with respect to the normal B of the optical axis C of the LED 4 are set to different angles (for example, as shown in FIG. 9), θa <θ2 In this case, the relative angular difference (θ2−θa) can be set to about 10 °. In this case, the camera 3 and the LED 4 are integrally configured as a unit, the relative angle difference (θ2−θa) is fixed, the unit is rotatably supported with respect to the frame, and the inclination thereof It is good to be able to adjust. The camera 3 alone or the LED 4 alone may be pivotally supported with respect to the frame so that the respective tilts can be adjusted.

  Adjustment of the tilt of the camera 3, the LED 4, or the unit in which these are integrated may be performed manually, or may be performed by motor drive or the like. When performing by motor drive etc., the display 2 is provided with an acceleration sensor so that the angle of the display screen 2a with respect to the installation surface can be detected, and according to the detected angle, the camera 3, the LED 4, or the camera 3 and You may enable it to adjust automatically the inclination of the unit which integrated LED4. In addition, the opening / closing angle or the opening / closing position of the stand 5 is detected to determine whether the installation surface is a desk or a wall, and depending on the situation, the inclination of the unit that integrates the camera 3, LED 4, or the camera 3 and LED 4 is determined. May be automatically adjusted. Furthermore, an atmospheric pressure sensor or the like is provided to detect the height position of the display 2 and automatically tilt the camera 3, the LED 4, or the unit in which the camera 3 and the LED 4 are integrated according to the detected height position. It may be possible to adjust. Depending on the detection result obtained by combining the detection results described above, the tilt of the camera 3, the LED 4, or the unit in which the camera 3 and the LED 4 are integrated may be automatically adjusted.

  Next, in the image display apparatus of the present embodiment, a first object detection process (object detection apparatus) for detecting the user's hand 7a as a detection target object will be described with reference to FIGS. To do.

  In FIG. 13, the upper stage “vsync” indicates image capture timing of the image sensor (image sensor) constituting the camera 3 (n frames from the left, n + 1 frames, n + 2 frames, n + 3 frames: n is 1, 2, 3,... The lower “infrared light” indicates the timing of the change in the light intensity of the illumination light of the LED 4 (here, infrared light).

  The control device 11 synchronizes with the frame rate of the image sensor of the camera 3 to apply a voltage to the LED 4 so as to emit light at the first light intensity, and lower than the first light intensity and less than zero light intensity. And a weak light-emitting mode in which a voltage is applied so as to emit light with a second light intensity that is greater than that. Here, zero light intensity indicates a state where no voltage is applied, that is, a state where the light is extinguished. Therefore, the weak light emission mode here does not include a state where the light is extinguished. For the sake of simplicity, in the present embodiment, the first light intensity is assumed to be 100%, and the second light intensity is half that of 50%. That is, when the image of the nth frame is acquired, the LED 4 emits light in the strong light emission mode, and when the image of the (n + 1) th frame is acquired, the LED 4 emits light in the weak light emission mode, and sequentially emits strong light. The mode and the weak light emission mode are repeated.

  FIG. 14A to FIG. 14D are diagrams for explaining the first object detection process. FIG. 14A shows an n-th frame image obtained when the LED 4 emits light in the strong light emission mode (first light intensity), and FIG. 14B shows the LED 4 in the weak light emission mode (second light intensity). The image of the (n + 1) th frame acquired when light was emitted at is schematically shown.

  In addition, in FIG. 14A, the horizontal rectangle at the upper left indicates that the light when the flashing illumination (fluorescent lamp, bad LED bulb, etc.) is turned on is reflected as a disturbance, FIG. 14B shows that such a disturbance is not reflected because the flashing light source is turned off. A substantially hand shape shown in the center of the image is an image relating to the user's hand 7a as a detection target object. In FIG. 14A, the LED 4 emits light in the strong light emission mode, and thus white (100%). FIG. 14B shows a state in which the LED 4 is reflected in gray (50% light intensity) because the LED 4 emits light in the weak light emission mode.

  First, an image of a difference {(n + 1) − (n)} between the nth frame acquired image in FIG. 14A and the n + 1th frame acquired image in FIG. 14B is obtained. This difference image is an image obtained by taking a difference in luminance value between corresponding pixels of both images. An image of this difference is shown in FIG. At this stage, since only the difference is taken, disturbance (horizontal rectangle) remains, and with this state, sufficient detection accuracy of the image related to the hand 7a as the detection target cannot be obtained.

  Therefore, in the first object detection process, by changing the light intensity of the illumination light, the part related to the disturbance is distinguished from the image related to the hand 7a as the detection target, and only the disturbance is excluded. . That is, as shown in FIG. 14 (d), the first light intensity (100%) related to the strong light emission mode is emitted in the nth frame, while the second light emission mode related to the weak light emission mode is used in the (n + 1) th frame. Since the light is emitted with the light intensity (50%), the brightness (luminance) of the image relating to the hand 7a as the detection target is approximately {(second light intensity) − (first light intensity)}, that is, 50 % -100% = about -50%. Therefore, it can be determined that an image related to a pixel having a luminance of around −50% is an image related to the hand 7a as a detection target. On the other hand, if the disturbance is 90% at the nth frame, for example, n + 1 Since it is 0% in the frame, the difference between the second light intensity and the first light intensity is 0% −90% = − 90%, and the image relating to the hand 7a as the detection target and the image relating to the disturbance are obtained. Can be distinguished.

  Therefore, for example, by setting -50 ± 10% as a threshold value for image extraction, and deleting an image related to a pixel having a luminance outside this range as a disturbance, as shown in FIG. An image obtained by extracting only the image portion related to the hand 7a can be obtained. Therefore, it is possible to improve the detection accuracy of the image related to the hand 7a as the detection target.

  Next, in the image display device of the present embodiment, a second object detection process (object detection device) for detecting the user's hand 7a as a detection target object will be described with reference to FIGS. To do.

  In FIG. 15, the upper “vsync” indicates image capture timing of the image sensor (image sensor) constituting the camera 3 (n frames from the left, n + 1 frames, n + 2 frames, n + 3 frames: n is 1, 2, 3,... The lower “infrared light” indicates the intensity change timing of the illumination light of the LED 4 (in this case, infrared light).

  The control device 11 synchronizes with the frame rate of the image sensor of the camera 3 to apply a voltage to the LED 4 so as to emit light at the first light intensity, and lower than the first light intensity and less than zero light intensity. And selectively switching between a weak light emission mode in which a voltage is applied so that light is emitted with a higher second light intensity and a light-off mode in which the light intensity is zero (that is, the light is turned off without applying a voltage). Here, it is assumed that light is repeatedly emitted in the order of the light-off mode, the weak light emission mode, and the strong light emission mode. For simplicity, it is assumed here that the first light intensity (strong) is 100%, the second light intensity (weak) is half the light intensity, and light extinction is zero. That is, when the image of the nth frame is acquired, the LED 4 is turned off, and when the image of the (n + 1) th frame is acquired, the LED 4 is emitted in the weak light emission mode, and the image of the (n + 2) th frame is acquired. When the LED 4 emits light, the LED 4 emits light in the strong light emission mode, and the turn-off mode, the weak light emission mode, and the strong light emission mode are sequentially repeated.

  FIG. 16A to FIG. 16D are diagrams for explaining the second object detection process. FIG. 16A shows an image of the nth frame acquired when the LED 4 is turned off, and FIG. 16B is acquired when the LED 4 is emitted in the weak light emission mode (second light intensity). FIG. 16C shows an image of the (n + 1) th frame obtained when the LED 4 emits light in the strong light emission mode.

  In FIGS. 16 (a) and 16 (c), a horizontally long rectangle is shown at the upper left, and the light when flashing illumination (fluorescent lamp, bad LED bulb, etc.) is turned on is reflected as disturbance. In FIG. 16B, the blinking illumination is turned off, and it is shown that such a disturbance is not reflected. A substantially hand shape shown in the center of the image is an image relating to the user's hand 7a as a detection target object. In FIG. In FIG. 16B, the LED 4 emits light in the weak light emission mode, so it is reflected in gray (50% light intensity). In FIG. 16C, the LED 4 emits light in the strong light emission mode, so white (50%). The light intensity is shown in FIG.

  Focusing on n frames to n + 2 frames, the portion (pixel) related to the hand 7a as the detection target illuminated by the LED 4 changes stepwise according to the change in the emission intensity of the LED 4 (in this case, it becomes brighter). Therefore, by comparing the images related to the three frames of the nth frame acquired image of FIG. 16A, the n + 1th frame acquired image of FIG. 16B, and the n + 2th frame acquired image of FIG. By extracting only pixel values that change as (n <n + 1 <n + 2), disturbance can be eliminated.

  In the second object detection process described above, the LED 4 is caused to emit light (or turn off) in three modes of the strong light emission mode, the weak light emission mode, and the light extinction mode. An image associated with four or more frames may be used by setting a mode that emits light with light intensity and / or a mode that emits light with a light intensity between a weak light emission mode and a light-off mode. Alternatively, the extinguishing mode may be omitted, and a mode in which light is emitted with a third light intensity smaller than the second light intensity according to the weak light emission mode may be set.

  Here, as shown in FIGS. 17 and 18, the order of light emission (light intensity change) by the LED 4 may be reversed. That is, you may make it light-emit repeatedly in order of a strong light emission mode, a weak light emission mode, and a light extinction mode. Since the processing in this case is the same as that shown in FIGS. 15 and 16, the description thereof is omitted. In this case, an image related to the three frames of the n-th frame acquired image in FIG. 18 (a), the (n + 1) th frame acquired image in FIG. 18 (b), and the n + 2th frame acquired image in FIG. 18 (c). And extracting only pixel values that change as (n> n + 1> n + 2), thereby eliminating disturbance.

  Next, in the image display device of this embodiment, a third object detection process (object detection device) for detecting the user's hand 7a as a detection target object will be described with reference to FIGS. 19 and 20. To do.

  In FIG. 19, the upper “vsync” indicates image capture timing of the image sensor (image sensor) constituting the camera 3 (n frames from the left, n + 1 frames, n + 2 frames, n + 3 frames: n is 1, 2, 3,... The lower “infrared light” indicates the timing of the change in the light intensity of the illumination light of the LED 4 (here, infrared light).

  The control device 11 synchronizes with the frame rate of the image sensor of the camera 3 to apply a voltage to the LED 4 so as to emit light at the first light intensity, and lower than the first light intensity and less than zero light intensity. And selectively switching between a weak light emission mode in which a voltage is applied so that light is emitted with a higher second light intensity and a light-off mode in which the light intensity is zero (that is, the light is turned off without applying a voltage). Here, it is assumed that light is repeatedly emitted in the order of the light-off mode, the weak light emission mode, and the strong light emission mode. For simplicity, in the present embodiment, the first light intensity is 100%, the second light intensity is 50% of the light intensity, and the extinction is zero. That is, when the image of the nth frame is acquired, the LED 4 is turned off, and when the image of the (n + 1) th frame is acquired, the LED 4 is emitted in the weak light emission mode, and the image of the (n + 2) th frame is acquired. When the LED 4 emits light, the LED 4 emits light in the strong light emission mode, and the turn-off mode, the weak light emission mode, and the strong light emission mode are sequentially repeated.

  FIG. 20A to FIG. 20D are diagrams for explaining the third object detection process. FIG. 20A shows an image of the nth frame acquired when the LED 4 is turned off, and FIG. 20B is acquired when the LED 4 is emitted in the weak light emission mode (second light intensity). FIG. 20C shows an image of the (n + 1) th frame acquired when the LED 4 emits light in the strong light emission mode.

  In FIGS. 20 (a) and 20 (c), a horizontally long rectangle is shown in the upper left corner, and the light when the flashing illumination (fluorescent lamp, bad LED bulb, etc.) is turned on is reflected as a disturbance. In FIG. 20B, since the blinking illumination is turned off, it is shown that such a disturbance is not reflected. A substantially hand shape shown in the center of the image is an image related to the user's hand 7a as a detection target object. In FIG. In b), the LED 4 emits light in the weak light emission mode, so it is reflected in gray (50% light intensity). In FIG. 20C, the LED 4 emits light in the strong light emission mode, so white (50%). The state of being reflected in (light intensity) is shown.

  In the second object detection process described above, pixels are extracted based on the magnitude change in luminance between the images related to the three frames and the target object is detected. In this third object detection process, the LED 4 The pixels to be extracted are selected based on the change rate of the emission intensity (for example, the ratio to the increase amount in this case).

  First, a difference between the nth frame acquired image in FIG. 20A and the n + 1th frame acquired image in FIG. 20B is obtained, and the brightness of the image is increased at a ratio corresponding to the increase in emission intensity. Just get. In order to eliminate noise (for example, blinking illumination light) included in this, a difference is further obtained from the acquired image of the (n + 2) th frame. At this time as well, only the target object can be extracted by extracting pixels that become bright at a ratio corresponding to the amount of increase in emission intensity. By setting it as such a process, the detection accuracy of an object can further be improved.

  The first to third object detection processes described above may be selectively performed according to the nature of the disturbance caused by the blinking light source or the like. For example, as an illumination characteristic detection unit that detects the characteristics of illumination (flashing light source or the like) existing in the field of view of the camera 3, a luminance sensor is provided to detect the flashing frequency of the flashing light source, and based on the detected frequency, An optimum one of the first to third object detection processes may be automatically selected and executed. Instead of such a luminance sensor, the characteristics of illumination (such as a blinking light source) existing in the field of view may be detected from an image captured by the camera 3.

  In the above-described embodiment, the case where a digital photo frame is used as the image display device has been described. However, the present invention is also applied to other devices having a motion detection camera and a display and having an image reproduction function, such as a personal computer, a tablet computer, a digital camera, a mobile phone, a PDA, and a digital television receiver. Can be applied.

  The embodiment described above is described for facilitating the understanding of the present invention, and is not described for limiting the present invention. Therefore, each element disclosed in the above embodiment is intended to include all design changes and equivalents belonging to the technical scope of the present invention.

  DESCRIPTION OF SYMBOLS 1 ... Digital photo frame, 2 ... Display, 2a ... Display screen, 3 ... Camera, 4 ... LED, 5 ... Stand, 6 ... Table, 6a ... Installation surface, 7 ... User, 7a ... Hand, 8 ... Camera support member, 8a ... rotation axis, 8b ... contact surface, 9 ... pedestal, 9a ... rotation axis, 11 ... control device, A ... optical axis of the camera, B ... normal passing through the center of the display screen, C ... optical axis of the LED, D: The normal of the installation surface.

Claims (12)

A display unit;
An imaging unit having the imaging optical system disposed in the display unit such that a normal line orthogonal to a part of the display surface of the display unit and an optical axis of the imaging optical system intersect;
An illumination unit that emits the illumination light arranged in the display unit such that a normal line orthogonal to a part of the display surface of the display unit and the illumination light intersect;
A support unit for supporting the imaging unit;
An image display apparatus comprising: an adjustment unit that automatically adjusts the support unit so that a normal line orthogonal to a part of the display surface of the display unit and the optical axis of the imaging optical system intersect . A detection unit for detecting the inclination of the display unit;
The adjustment unit adjusts the support unit based on the inclination.
The image display device according to claim 1. The detection unit detects an angle of the display unit with respect to a setting surface of the display unit,
The adjustment unit adjusts the support unit based on the angle.
The image display device according to claim 2. A detection unit for detecting a height at which the display unit is installed;
The adjustment unit adjusts the support unit based on the height.
The image display device according to claim 1. The adjusting unit adjusts the normal line and the optical axis so that the display surface side of the display unit intersects.
The image display apparatus as described in any one of Claims 1-4. The illumination unit emits the illumination light with a plurality of light intensities,
The imaging unit images the subject illuminated by the illumination unit.
The image display device according to any one of claims 1 to 5. A display control unit configured to control the display unit based on the subject imaged by the imaging unit;
The image display device according to claim 6. The illumination unit emits the illumination light by switching between a first light intensity and a second light intensity that is smaller than the first light intensity.
The image display apparatus as described in any one of Claims 1-7. The imaging unit captures images at a predetermined interval,
The illumination unit emits the illumination light by switching between the first light intensity and the second light intensity based on the predetermined interval.
The image display device according to claim 8. The illumination unit emits the illumination light by switching between the first light intensity, the second light intensity, and a third light intensity smaller than the second light intensity.
The image display device according to claim 8 or 9. The illumination unit illuminates an operation for changing the display of the display unit with a plurality of light intensities.
The image display apparatus as described in any one of Claims 1-10. The illumination unit emits the illumination light by switching light intensity of the illumination light based on disturbance included in captured image data captured by the imaging unit.
The image display apparatus as described in any one of Claims 1-11.

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