JP2013218019A - Projection device, projection method and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To simplify user setting operation as much as possible for projecting an image suitable for the environment.SOLUTION: A projection device includes: projection systems 11-16 that form and project an image corresponding to given image information; photographic systems 17-21 for photographing an image including projection direction of the projection systems 11-16; an image selection table storage unit 24A and an image storage unit 24B for storing a plurality of image information associated with a shape; a photographic image processing unit 20 for extracting the shape of a portion associated with a projection object from an image obtained by the photographic systems 17-21; and a CPU22 that selects image information from the image storage unit 24B on the basis of the extracted shape, and gives the selected image information to the projection systems 11-16 for projection.

Description

  The present invention relates to a projection apparatus, a projection control method, and a program.

  A technique for an illuminating device capable of coating an object to be irradiated having an arbitrary shape with irradiation light with high accuracy is considered. (For example, Patent Document 1)

JP 2009-049007 A

  In the technique described in the above patent document, the contour of the coating light is cut according to the shape of the irradiated object, and the contour of the coating light is corrected according to the positional relationship.

  Including the technique described in this patent document, the image itself to be projected toward the projection target must be selected by the user. That is, the user needs to perform various complicated settings including image selection such as the selection of the image according to the projection environment, the focus adjustment according to the projection position, and the projection distance.

  The present invention has been made in view of the above circumstances, and its object is to provide a projection device, a projection method, and a projection method capable of projecting an image suitable for the environment by simplifying a user's setting operation as much as possible. To provide a program.

  According to one aspect of the present invention, a projection unit that forms an image according to given image information and projects the projected image onto an object to be projected, an image storage unit that stores in advance image information associated with an object, and a projection by the projection unit Image capturing means for capturing an image including a direction, image processing means for extracting an object from an image obtained by the image capturing means, and image information associated with the image storage means based on the object extracted by the image processing means. An image selecting unit to be selected; and a projection control unit that gives the image information selected by the image selecting unit to the projecting unit and projects an image onto a projection object other than the object by the projecting unit. Features.

  According to the present invention, it is possible to project an image suitable for the environment by simplifying the user's setting operation as much as possible.

The figure which illustrates the use environment of the projection apparatus which concerns on one Embodiment of this invention. FIG. 3 is a block diagram showing a functional circuit configuration of the projection apparatus according to the embodiment. The figure which illustrates the contents of the image selection table memorized in the program memory of Drawing 2 concerning the embodiment. The flowchart which shows the processing content at the time of the object projection mode selection especially concerning the embodiment. The figure which illustrates the use environment of the form lighting apparatus which concerns on other embodiment of this invention.

  Hereinafter, an embodiment in which the present invention is applied to a projection apparatus will be described with reference to the drawings.

  FIG. 1 is a diagram illustrating a usage environment of a projection apparatus 10 according to the present invention. In the figure, a projection device 10 is mounted on a table TB, the leg portion FT being extended to adjust the projection direction. When a certain object (object) OJ having a shape set in advance by the projection device 10 is illuminated, for example, a flower bin, in the state where the normal projection mode is set, normal projection drive, that is, the surface of the flower bin is also applied. While an image based on the image signal is projected with a partial image projected, the object projection mode is set, corresponding to the position of the object OJ, for example, the object OJ on the background BG The projected image PI is projected at a position to be moved, for example, a position immediately above.

  The projection apparatus 10 includes a zoom lens and a focus lens in the projection lens system, and particularly in a state where the object OJ is recognized in the object projection mode, a necessary projection angle is automatically selected to set the object OJ or the background BG position. The image PI is projected in focus.

  FIG. 2 is a diagram for mainly explaining the functional configuration of the electronic circuit of the projection apparatus 10 according to the present embodiment. In the figure, the image data input by the input processing unit IP is digitized by the input processing unit IP as necessary, and then sent to the projection image driving unit 11 via the system bus SB.

  The projection image drive unit 11 multiplies a frame rate according to a predetermined format, for example, 120 [frames / second], the number of color component divisions, and the number of display gradations, according to the transmitted image data. The micromirror element 12 is driven to display by faster time-division driving.

  The micromirror element 12 performs a display operation by individually turning on / off each inclination angle of a plurality of micromirrors arranged in an array, for example, WXGA (horizontal 1280 pixels × vertical 768 pixels) at high speed. Then, an optical image is formed by the reflected light.

  On the other hand, R, G, B primary color lights are emitted cyclically from the light source unit 13 in a time division manner. The light source unit 13 includes an LED, which is a semiconductor light emitting element, and repeatedly emits R, G, and B primary color lights in a time division manner. The LED included in the light source unit 13 may include an LD (semiconductor laser) or an organic EL element as an LED in a broad sense. The primary color light from the light source unit 13 is totally reflected by the mirror 14 and applied to the micromirror element 12.

  Then, an optical image is formed by the reflected light from the micromirror element 12, and the formed optical image is projected to the outside via the projection lens unit 15 and displayed.

  The projection lens unit 15 includes a focus lens for moving a focus position and a zoom lens for changing a zoom (projection) angle of view in an internal lens optical system, each of which is a lens motor (M). The position along the optical axis direction is selectively driven by a gear mechanism 16 (not shown).

  A photographing lens unit 17 is disposed adjacent to the projection lens unit 15. The photographing lens unit 17 includes a focus lens for moving a focus position, and has a photographing field angle that covers the projection field angle at the widest angle of the projection lens unit 15. An external optical image that enters the photographing lens unit 17 is formed on a CMOS image sensor 18 that is a solid-state imaging device.

  An image signal obtained by imaging with the CMOS image sensor 18 is digitized by the A / D converter 19 and then sent to the captured image processing unit 20.

  The captured image processing unit 20 scans and drives the CMOS image sensor 18 to execute a capturing operation, and performs image processing such as contour extraction on image data obtained by capturing, so that the image is processed as described later. The position and shape of the object OJ and background BG in FIG. 1 are extracted.

  In addition, the photographed image processing unit 20 drives a lens motor (M) 21 for moving the focus lens position of the photographing lens unit 17.

  The CPU 22 controls all the operations of the above circuits. The CPU 22 is directly connected to the main memory 23 and the program memory 24. The main memory 23 is composed of, for example, an SRAM and functions as a work memory for the CPU 22. The program memory 24 is composed of an electrically rewritable nonvolatile memory, such as a flash ROM, and stores an operation program executed by the CPU 22, various fixed data, and the like.

The program memory 24 includes an image selection table storage unit 24A and an image storage unit 24B as illustrated.
FIG. 3 illustrates the concept of the contents of the table stored in the image selection table storage unit 24A. As shown in the figure, a plurality of sets of data are registered in advance by associating “extracted shape”, “image number”, and “projection position (to the object)” as a set of data.
The image storage unit 24B pre-registers a plurality of image data associated with the image numbers stored in the image selection table storage unit 24A.

  The CPU 22 controls the projection apparatus 10 by reading out the operation program, fixed data, and the like stored in the program memory 24, developing and storing them in the main memory 23, and executing the program. To do.

  The CPU 22 executes various projection operations according to operation signals from the operation unit 25. The operation unit 25 receives key operation signals of some operation keys provided in the main body of the projection apparatus 10 and sends signals corresponding to the received key operation signals to the CPU 22.

  The operation keys provided in the operation unit 25 include, for example, a power key for operating on / off of the power of the projection apparatus 10, a mode switching key for switching between the normal projection mode and the object projection mode, and the like.

The CPU 22 is further connected to the sound processing unit 26 via the system bus SB.
The sound processing unit 26 includes a sound source circuit such as a PCM sound source, converts the sound signal given during the projection operation into an analog signal, drives the speaker unit 28 to emit sound, or generates a beep sound or the like as necessary.

Next, the operation of the above embodiment will be described.
The operation described below is executed after the CPU 22 expands the operation program read from the program memory 24 and the standard data in the main memory 23 as described above. The operation program and the like stored in the program memory 24 are not limited to those stored in the program memory 24 at the time of factory shipment of the projection apparatus 10, but install a version upgrade program after the user purchases the projection apparatus 10. Including the contents.

  FIG. 4 shows the processing contents of the operation executed by the CPU 22 particularly in the object projection mode. Initially, the CPU 22 determines whether or not the operation mode is selected on the object projection mode side based on the operation state of the mode key on the operation unit 25 (step S101).

  If it is determined that the object projection mode is not selected, the CPU 22 determines that the normal projection mode is selected, projects an image corresponding to the image signal (step S102), and starts from step S101. Return to the process.

  If it is determined in step S101 that the object projection mode is selected, the CPU 22 has not yet recognized the object, and the CMOS image sensor 18 takes an image in the projection direction while projecting white light. (Step S103).

  At the time of this photographing, the photographed image processing unit 20 creates a distance information map of at least several tens of points by performing scanning by the automatic focusing function with respect to the range irradiated with the white light in the photographed image.

  The CPU 22 causes the photographed image processing unit 20 to perform image processing such as contour extraction on the image data obtained by photographing, and extracts a target shape that can be an object within the white light irradiation range in the photographed image ( Step S104).

  In response to the extraction processing in the photographed image processing unit 20, the CPU 22 determines whether or not a candidate that can be an object has been extracted depending on whether or not any shape has been extracted (step S105).

  If it is determined that the shape cannot be extracted and the object candidate cannot be extracted, the CPU 22 returns to the process from step S101.

  If it is determined in step S105 that the object candidate has been extracted, the CPU 22 determines whether the extracted object shape matches the content stored in the image selection table storage unit 24A of the program memory 24. (Step S106).

  If it is determined that there is no matching object shape stored in the image selection table storage unit 24A, the CPU 22 returns to the process from step S101.

  If the CPU 22 determines that the shape of the object extracted in step S106 matches the content stored in the image selection table storage unit 24A of the program memory 24, the CPU 22 selects an image based on the image number associated with the matched shape. Corresponding image data is read from the storage unit 24B (step S107).

  Using the read image data, the image selection table storage unit 24A reads the shooting position corresponding to the object, and then the CPU 22 reads the shot image, the position and size of the object shape in the image, and the image selection table. Based on the projection position read from the table of the storage unit 24A and the up and down of the projection direction calculated from the current posture obtained from the distance information map in the captured image, the optimal projection position, the enlargement ratio of the projection image, and the projection focus position The projection condition is set (step S108), and projection based on the set projection condition is started (step S109).

  For example, in the environment shown in FIG. 1 above, when the object OJ is irradiated with the portable illumination device 10 selecting the object projection mode, the shape of the object OJ is extracted from the captured image, so that the user US A state in which the projected image PI of “plum branches with a warbler on the top” is projected on the object OJ.

  At this time, the position of the projection image PI to be projected and the zoom lens position of the projection lens unit 15 are controlled according to the position and size of the object OJ in the photographed image, and the projection image PI is projected by narrowing the projection angle of view to the maximum. Set to automatically.

  Further, the CPU 22 reads the distance information of the upper position of the object OJ from the distance information map with respect to the distance for projecting the projection image PI, thereby moving the focus lens of the projection lens unit 15 so that the projection image PI can be accurately obtained. Automatically set the distance to focus.

  Here, the position where the image corresponding to the object shape in the image is projected will be described in detail.

  In step S103, a distance information map of several tens of positions is created for the captured image range. By using this distance information map, an object reference point (for example, for each object shape) (for example, The coordinates of the point P) in FIG. 3 in the captured image range are examined.

  An image reference point (for example, point Q in FIG. 1) is also set for each image corresponding to the object shape. The information of “projection position (with respect to the object)” stored in the image selection table storage unit 24A projects the image by matching the image reference point to which coordinate when the object reference point is the origin. It is the coordinate information of the projection part which shows. The object reference point and the image reference point can be freely set and stored in advance by the user.

  Then, the coordinate information of the projected position of the image is read from the information of “projected position (to the object)”, and the projected position of the image obtained from the information of “projected position (to the object)” with the above-mentioned object reference point as the origin. The image is projected so that the coordinates of and the image reference point coincide.

  Specifically, for example, referring to FIG. 3, when the extracted shape is a vase, the projection position coordinates are (0, 0), the object reference point P, and the image reference of the image corresponding to the image number 1 The image is projected so that the point Q matches.

  By determining the projection position in this way, as shown in FIG. 1, an image corresponding to the object shape, such as projecting the projection image PI of “plum branch with a warbler on the top” of the object OJ, is projected. Projection can be performed at a position suitable for the object shape.

  In this embodiment, the projected image is projected onto the screen so that it is not projected onto the object itself. By displaying in this way, the background of the object that is actually placed in front of the screen is displayed on the screen. Can be used as

  As other projection examples, for example, except for the inside of the extracted shape itself (black image projection) for the object of the shape of the “ship”, the image of the “sea” is projected using the entire surrounding area, etc. Depending on the data stored in the image selection table storage unit 24A and the image storage unit 24B of the program memory 24, more various expressions are possible.

  With the projection image PI corresponding to the shape of the object thus projected, the CPU 22 waits for a key operation for canceling the projection, for example, a mode switching key operation (step S110).

  When the key operation for canceling the object projection mode is performed, the CPU 22 determines in step S110 and cancels the projection of the image that has been executed so far (step S111). The process returns to step S101.

  In the present embodiment, the contents of the table stored in the image selection table storage unit 24A are obtained by associating an “extraction shape” of an object, an “image number”, and a “projection position (with respect to the object)” as a set of data. Although it is registered in advance, for example, the “pattern” or “color” of the object may be registered in advance in association with the “image number” and “projection position (with respect to the object)” These combinations of the “shape”, “pattern”, and “color” of the object may be registered in advance in association with the “image number” and “projection position (with respect to the object)”.

  In this way, not only the shape of the object but also other factors of the object can be used for selecting the projection image, so that it is possible to provide image projection rich in variations.

  As described above in detail, according to the present embodiment, it is possible to project an image suitable for the environment by simplifying the user's setting operation as much as possible.

  In the above embodiment, depending on the shape of the extracted object, it is possible to automatically set an image to be projected to an appropriate position on the background side of the object instead of directly projecting an image on the object. In addition, various images suitable for objects can be projected.

  In particular, in the above embodiment, the photographing lens unit 17 of the photographing system and the projection lens unit 15 of the projection system both have the autofocus function, and the focal distances for a plurality of points in the photographed image are acquired. An image can be projected in a state where it is accurately focused on the surface, and a natural and high-quality image can be projected without a sense of incongruity for the user.

  Further, in the above embodiment, the projection lens unit 15 has a zoom function for changing the projection angle of view, and is configured to project an image with the projection angle of view as narrow as possible. A light image formed by the light and the micromirror element 12 can be used more effectively, and a bright and precise image can be projected.

  Further, in the above-described embodiment, the case of the projection device 10 used in a stationary manner has been described. However, as another embodiment of the present invention, a case suitable for the portable lighting device 10 ′ having a projector function will be described.

  FIG. 5 is a diagram illustrating a use environment of a portable lighting device 10 ′ according to another embodiment of the present invention. In the same figure, when an object OJ, for example, a flower bottle, whose shape has been set in advance by the portable lighting device 10 'carried by the user US is illuminated, the flashlight (flashlight) mode is set at that time. In the state, it is merely limited to irradiating a circular white light, while in the state in which the object projection mode is set, for example, a position corresponding to the object OJ on the background BG, for example, directly above the object OJ. Projection image PI is projected onto the position.

  The portable illumination device 10 'includes a zoom lens and a focus lens in the projection lens system, and in the flash light mode, the portable illumination device 10' is set in the infinity direction at a certain irradiation angle range, for example, an angle set by the user US in 5 ° to 30 °. While irradiating white light to focus, particularly in the state of recognizing the object OJ in the object projection mode, the necessary projection angle is automatically selected to focus on the background BG position and project the image PI.

  Such a functional circuit configuration inside the portable lighting device 10 ′ can be basically configured in the same manner as that shown in FIG.

  However, the portable illumination device 10 'does not input an image signal and project the corresponding image in real time, but irradiates the entire surface with white light in the normal flash light mode. The configuration of the part IP can be omitted.

  On the other hand, in the portable lighting device 10 ′, since it is necessary to recognize the correct projection position with respect to the object extracted from the captured image in the object projection mode, as a configuration for detecting the posture of the portable lighting device 10 ′, for example, a three-dimensional acceleration sensor is used. Shall be provided.

  By providing the three-axis acceleration sensor, it becomes possible to detect a change in posture angle of the portable lighting device 10 ′ including gravitational acceleration in the three-dimensional space, and to recognize and project the correct projection position on the object. be able to.

  Although not described in the above embodiment, the audio information can be selected in association with the shape of the object extracted by the image selection table storage unit 24A of the program memory 24, and the corresponding audio is selected when the image to be projected is selected. For example, “squeak of warbler”, “sound of sea bream and seagulls” or various classical music pieces may be output by the speaker unit 28.

  Moreover, although the said embodiment demonstrated the projection apparatus which has the projector function of the DLP (trademark) system in which the projection lens part 15 used the semiconductor light emitting element, this invention does not limit a light emitting element, a projector system, etc. .

  In the above embodiment, the photographing lens unit 17 is configured to have a photographing field angle that covers the projection field angle at the widest angle of the projection lens unit 15, and an image in the projection direction is captured by the CMOS image sensor 18. For example, the imaging lens unit 17 may be configured to capture an image in another direction instead of the projection direction. For example, the imaging lens unit 17 includes a plurality of the imaging lens units 17 and includes a projection device. The surroundings may be photographed.

  In the above-described embodiment, the corresponding projection image is projected onto the screen so that it is not projected onto the object itself. Expression is possible.

  In addition, the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the scope of the invention in the implementation stage. Further, the functions executed in the above-described embodiments may be combined as appropriate as possible. The above-described embodiment includes various stages, and various inventions can be extracted by an appropriate combination of a plurality of disclosed constituent elements. For example, even if some constituent requirements are deleted from all the constituent requirements shown in the embodiment, if the effect is obtained, a configuration from which the constituent requirements are deleted can be extracted as an invention.

Hereinafter, the invention described in the scope of claims of the present application will be appended.
According to the first aspect of the present invention, there is provided a projection unit that forms an image according to given image information and projects the image on a projection object, an image storage unit that stores in advance image information associated with an object, and the projection unit. Image capturing means for capturing an image including a projection direction, image processing means for extracting an object from an image obtained by the image capturing means, and image information associated with the image storage means based on the object extracted by the image processing means An image selection means for selecting the image, and a projection control means for supplying the image information selected by the image selection means to the projection means and projecting an image onto a projection object other than the object by the projection means. It is characterized by.

  According to a second aspect of the present invention, in the first aspect of the present invention, the image storage means stores image information in association with at least one of the shape, pattern, or color of the object.

  According to a third aspect of the invention, in the first or second aspect of the invention, the projection control means projects the image so that the image is projected at a position corresponding to the shape of the object extracted by the image processing means. The image information selected by the selection means is given to the projection means.

  The invention according to claim 4 is the invention according to any one of claims 1 to 3, wherein the projection control means causes the projection means to project an image based on the image information including the object. And

  According to a fifth aspect of the present invention, in the invention according to any one of the first to fourth aspects, the projection unit has an automatic focus function for changing a focus distance of an image to be projected, and the photographing unit performs photographing. A distance acquisition function for acquiring a distance to an arbitrary position in the image, wherein the projection control means uses the distance acquisition function of the photographing means to calculate the distance to the object or its background extracted by the image processing means; The in-focus distance is set by the auto-focus function of the projection unit according to the acquired distance.

  According to a sixth aspect of the present invention, in the invention according to any one of the first to fifth aspects, the projection unit has an automatic zoom function of changing a field angle of an image to be projected, and the projection control unit includes the image The projection angle of view is set by the automatic zoom function of the projection unit according to the position in the image of the object extracted by the processing unit.

  The invention described in claim 7 is an apparatus including a projection unit that forms an image according to given image information and projects the image on a projection object, and a photographing unit that captures an image including a projection direction of the projection unit. Based on the image storage step for preliminarily storing image information associated with the object, the image processing step for extracting the object from the image obtained by the photographing unit, and the object extracted in the image processing step. An image selection step for selecting image information associated with the content stored in the image storage step, and image information selected in the image selection step is provided to the projection unit, and the projection unit applies a projection object other than the object to the projection object. And a projection control step of projecting an image.

  According to an eighth aspect of the present invention, there is provided an apparatus including a projection unit that forms an image according to given image information and projects the image on a projection object, and a photographing unit that captures an image including a projection direction of the projection unit. A program executed by a built-in computer, comprising: an image storage unit that stores image information associated with an object in advance; an image processing unit that extracts an object from an image obtained by the photographing unit; and the image processing unit. Based on the extracted object, image selection means for selecting image information associated with the content stored in the image storage means, and image information selected by the image selection means is provided to the projection unit, and the projection unit provides the object It is made to function as a projection control means for projecting an image onto an object other than the projection object.

  DESCRIPTION OF SYMBOLS 10 ... Projection apparatus, 10 '... Portable illumination apparatus, 11 ... Projection image drive part, 12 ... Micromirror element, 13 ... Light source part, 14 ... Mirror, 15 ... Projection lens part, 16 ... Lens motor (M), 17 ... Shooting lens unit, 18 ... CMOS image sensor, 19 ... A / D converter, 20 ... Captured image processing unit, 21 ... Lens motor (M), 22 ... CPU, 23 ... Main memory, 24 ... Program memory, 24A ... Image Selection table storage unit, 24B ... image storage unit, 25 ... operation unit, 26 ... audio processing unit, 28 ... speaker unit, BG ... background, FT ... (projection device) leg unit, IP ... input processing unit, OJ ... object, PI: projected image, SB: system bus, TB: table, US: user.

Claims (8)

Projecting means for forming an image according to given image information and projecting the image on a projection object;
Image storage means for storing in advance image information associated with the object;
Photographing means for photographing an image including a projection direction by the projection means;
Image processing means for extracting an object from the image obtained by the photographing means;
Image selection means for selecting image information associated from the image storage means based on the object extracted by the image processing means;
A projection apparatus comprising: projection control means for supplying image information selected by the image selection means to the projection means, and causing the projection means to project an image onto a projection object other than the object.   The projection apparatus according to claim 1, wherein the image storage unit stores image information in association with at least one of a shape, a pattern, or a color of the object.   The projection control means provides the projection means with image information selected by the image selection means so that an image is projected at a position corresponding to the shape of the object extracted by the image processing means. Item 3. The projection device according to Item 1 or 2.   4. The projection apparatus according to claim 1, wherein the projection control unit causes the projection unit to project an image based on the image information including the object. The projection means has an automatic focus function for changing a focusing distance of an image to be projected,
The imaging means has a distance acquisition function for acquiring a distance to an arbitrary position in the image to be captured,
The projection control means acquires the distance extracted to the object or the background side extracted by the image processing means by the distance acquisition function of the photographing means, and is focused by the auto focus function of the projection means according to the acquired distance. The projection apparatus according to claim 1, wherein a distance is set. The projection means has an automatic zoom function for changing the angle of view of the image to be projected,
6. The projection according to claim 1, wherein the projection control unit sets a projection angle of view by an automatic zoom function of the projection unit according to a position in the image of the object extracted by the image processing unit. apparatus. A projection method in an apparatus including a projection unit that forms an image according to given image information and projects the image on a projection, and an imaging unit that captures an image including a projection direction in the projection unit,
An image storage step for storing image information associated with the object in advance;
An image processing step of extracting an object from the image obtained by the photographing unit;
An image selection step of selecting image information associated with the content stored in the image storage step based on the object extracted in the image processing step;
A projection method comprising: a projection control step of supplying image information selected in the image selection step to the projection unit, and causing the projection unit to project an image onto a projection object other than the object. A program executed by a computer built in a device including a projection unit that forms an image according to given image information and projects the image on a projection object, and a photographing unit that captures an image including the projection direction of the projection unit. There,
The computer
Image storage means for storing in advance image information associated with the object;
Image processing means for extracting an object from the image obtained by the photographing unit;
Based on the object extracted by the image processing means, the image selection means for selecting the associated image information from the contents stored in the image storage means, and the image information selected by the image selection means is given to the projection unit, and A program that causes a projection unit to function as a projection control unit that projects an image onto a projection object other than the object.

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