• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The apparatus includes a first light modulation element (11) for modulating a first light emitted from a light source (1) and for generating a second light, and a second light modulation element (12) for modulating the second light light. The first element is configured to receive the first light on a modulatable surface of pixels that can modulate the first light, the modulatable pixel surface including an effective pixel surface that can modulate the first light and a peripheral peripheral pixel surface. the effective area of pixels. The apparatus further includes a controller configured to control pixels of the peripheral surface so that light from the peripheral surface does not reach the second element.
    公开号:FR3070072A1
    申请号:FR1857375
    申请日:2018-08-08
    公开日:2019-02-15
    发明作者:Hiroyuki Kodama;Takehito Kawasumi;Yuuki MAEDA
    申请人:Canon Inc;
    IPC主号:
    专利说明:

    BACKGROUND OF THE INVENTION
    Field of 1 / invention.
    [0001J
    The present invention relates to image projection (a projector). Description of the Prior Art [0002] Certain projectors modulate, target plane, coming from a device such as a source one by one by means of a type reflection (a panel
    There may be light from reflection liquids).
    modulation
    projected of makes that the illuminating light, a surf ace ineffective situated at outside of effective of pixels of 1'élément modulation modulating the. illuminating light for purposes of image, es t also reflected and projected: target.
    of projections on the plane [0003] As a solution to this lighting surface light disclosed by the Japanese patent published before examination n ° ("JP") 2008-003215 comprises a plate forming a screen against light comprising an opening at a position combined with, a light modulating element and a mechanism for adjusting the position of the screen plate 25 against the light so that the illuminating light which has passed through the opening only penetrates the effective pixel area of the light modulation element.
    However, the plate forming a screen against light which receives light from the light source of the projector disclosed by patent JP 2008-003215 can deform thermally and cause the illuminating light to illuminate the ineffective surface. In addition, the mechanism for adjusting the position of the light shielding plate complicates the structure.
    SUMMARY OF THE INVENTION The present invention provides an image projection apparatus of simple structure for reducing light projected outside an effective pixel surface of a light modulation element.
    A first aspect of the present invention relates to an image projection apparatus as defined by points [1] to [8].
    [1] Image projection apparatus, comprising:
    a first light modulation element configured to modulate a first light emitted from a light source and to generate a second light; and a second light modulation element configured to modulate the second light, characterized in that the first light modulation element is configured to receive the first light on a modular surface of pixels which can modulate the first light, the modular surface of pixels comprising an effective area of pixels which can modulate the first light and a peripheral surface of pixels disposed at the periphery of the effective area of pixels, in that the image projection apparatus further comprises a controller configured to control pixels of the peripheral surface of pixels so that light from the peripheral surface of pixels does not reach the second light modulating element.
    [2] An image projection apparatus according to [1], further comprising an optical imaging system configured to image the second light on the second light modulation element;
    [3] An image projection apparatus according to [1], wherein the first light modulation element is a transmission type liquid crystal panel, wherein, the image projection apparatus further comprises a polarization plate disposed on an optical path from the first light modulation element to the second light modulation element, and in which the controller controls the pixels of the peripheral surface of pixels so that the polarization plate absorbs or reflects pixel light from the peripheral pixel surface.
    [4] An image projection apparatus according to [1], wherein the controller controls the pixels of the peripheral surface of pixels so as to bring the peripheral pixels into a black display state.
    [5] An image projection apparatus according to [1], wherein the first light modulation element is a reflection type liquid crystal panel, wherein the image projection apparatus further comprises a splitter polarization disposed on an optical path from the first light modulating element to the second light modulating element, and in which the controller controls the peripheral pixels so that the light from the peripheral pixels is directed in a direction different from that the second light modulation element through the polarization splitter;
    [6] An image projection apparatus according to [1], further comprising a modification device configured to modify a position of the effective pixel surface within the modular pixel surface of the first light modulation element.
    [7] An image projection apparatus according to [1], wherein the first light modulation element has resolutions in two orthogonal directions which correspond to a quarter, or more, of those of the second light modulation element.
    [8] An image projection apparatus according to [1], wherein the effective pixel area of the first modulation element has a shape similar to an effective pixel surface which modulates the second light in the second light modulation element.
    Other features of the present invention
    appear at reading, of the following description of real modes isation given as an example in himself referring to of attached drawings. BRIEF DESCRIPTION OF THE DRAWINGS[0008] lh figure 1 is a sectional view of a structure of dl 1 optical system s of a projector according to a first mode of realisation of the present invention.[0009] The "3 figure 2 represents a first element of
    light modulation and a second light modulation element according to the present embodiment.
    Figure 3 is a sectional view of a detailed structure of the optical system of a projector according to the present embodiment.
    Figure 4 is a flowchart of modulation control processing applied to the first modulation element of the projector according to the present embodiment.
    FIG. 5 is a flowchart for processing effective pixel surface adjustment applied to the first light modulation element of the projector according to the present embodiment.
    DESCRIPTION OF THE EMBODIMENTS We will now describe embodiments according to the present invention with reference now to the accompanying drawings.
    FIRST EMBODIMENT FIG. 1 represents a whole optical system of a projector as an image projection apparatus according to a first embodiment according to the present invention. The projector displays a projected image based on an input image signal supplied by an image providing apparatus, such as a personal computer not shown. The optical system includes an illuminating optical system for illuminating a first light modulating element 11 with illuminating light (first light) from a light source unit 13, and an optical imaging system for imaging a light modulated in luminance (second light) whose luminance has been modulated by the first light modulation element 11 on a second light modulation element 12. The present embodiment uses a liquid crystal panel reflection type with respect to the first and second light modulation elements 11 and 12.
    The light source unit 13 comprises a light source 1, such as a mercury lamp under ultra-high pressure and a xenon lamp, and a reflector 2 intended to reflect light from the source 1. The light source unit 13 can use an LED and a laser. Alternatively, the present embodiment may use a light source unit which uses a fluorescent body to be excited by a laser beam and which emits fluorescent light.
    The optical illumination system comprises a first lens of the fly eye type 3, a second lens of the fly eye type 4, a polarization conversion element 5, a first polarization beam splitter ("PBS") 6, and a first system 7 of lenses. The optical imaging system images the luminance modulated light from the light modulation element 11 on the second light modulation element 12, and comprises a first lens system 7 and a second lens system 8 lenses.
    The illumination light from the light source unit 13 is divided into a plurality of light fluxes by the first fly eye type lens 3 and each light flux is condensed. The plurality of light streams pass through the second fly eye type lens 4 and form a plurality of light source images. The polarization converting element 5 is located near a position at which the light source image is formed.
    A plurality of light source streams as non-polarized light incident on the polarization converting element 5 are converted into polarized light (here, P-polarized light) having a specific polarization direction by the first polarization conversion element 5, and penetrate the first PBS 6. The P polarization light which has passed through the first PBS 6 is condensed by the first system 7 of lenses, reaches and illuminates the first light modulation element 11. The first light modulation element 11 is driven on the basis of the above-mentioned input image signal, modulates the illumination light, generates and reflects the luminance modulated light.
    The luminance modulated light (an S-polarized light) emitted from the first light modulation element 11 is condensed by the first system 7 of lenses, reflected by the first PBS 6, condensed by the second system 8 of lenses, reflected by a second PBS 9, and imaged on the second light modulation element 12. The light (P-polarized light) which has not been modulated in luminance by the first light modulation element 11 passes through the first PBS 6 and is returned to the light source unit side.
    The second light modulation element 12 is controlled on the basis of the input image signal mentioned above, modulates the light modulated in luminance, generates and. reflects an image light. Image light (P-polarized light) emitted from the second light modulation element 12 passes through the second PBS 9, and is projected onto a target plane, such as a screen not shown, by the projection lens 10 Light (S-polarized light) that has not been modulated by the second light modulating element. 12 is reflected on the second PBS 9 and is returned to the light source unit side.
    In the projector according to the present embodiment, the first light modulation element 11 controls the luminance level of the incident light (light modulated in luminance) of each image surface of the second light modulation element 12 , and the second light modulation element 12 controls the luminance level of the emitted light (image light) of each pixel. This two-stage control of the luminance level of light provides high contrast and multiple gradations. For example, suppose that the contrast obtained by the first PBS 6 and the first light modulation element 11 is 200: 1 and that the contrast ratio obtained by the second PBS 9 and the second light modulation element 12 is 5,000: 1. The projector can then obtain the contrast of 1,000,000: 1.
    In this case, the optical image forming system which comprises the first lens system 7 and the second lens system 8 constitutes a telecentric optical system on both sides, on the side of the first light modulation element and on the side second light modulation element. Imaging magnification is a system element
    The optical image of the first light modulation 11 modulated in luminance modulation of and projected light 12.
    on the second panel element of the first upper light 12, and element that of the
    Consequently, light modulation 11 can second element for modulating the size of the surface of the first light modulation element 11 that penetrates the illumination light can be greater than that of the second light modulation element 12 that penetrates the light modulated in luminance. This is due to the fact that the light density of the first light modulation element 11 that the illuminating light penetrates is lower than that of the second light modulation element 12 that the luminance modulated light from the first modulation element penetrates. of light 11 (with the reflectance of approximately 60% to 80%). Overall, the life of the light modulation element becomes shorter as the light density increases. Thus, a drop in the light density on the first light modulation element 11 prevents the lifetime of the first light modulation element 11 from being shorter than that of the second light modulation element 12. In d in other words, the durability of the projector can be improved.
    FIG. 2 schematically represents a size relationship between the first light modulation element 11 and the second light modulation element 12 and a relationship between a modular surface of pixels and an effective surface of pixels. On the left side of FIG. 2, the mark B1 designates the modular surface of pixels of the first light modulation element 11, and the marker A1 designates the effective surface of pixels inside the modular surface of pixels B1. A surface C1 represented by a dashed line represents a surface of incidence of light of the modular surface of pixels B1 which the illumination light penetrates. The light incidence surface C1 is set larger than the effective area of pixels A1 to some extent. On the right side of FIG. 2, the mark B2 designates the modular pixel surface of the second light modulation element 12, and the marker A2 designates an effective pixel surface fixed with the same order of size or slightly smaller than the surface modular of pixels B2. In the second light modulation element 12, the luminance modulated light coming from the first light modulation element 11 penetrates a light incidence surface C2 of the same size or slightly larger than the effective surface of pixels A2.
    When the effective area of pixels A2 of the second light modulation element 12 is inversely projected onto the first light modulation element 11 via the optical image-forming system (7, 8) , a surface in which an image is formed (conjugate) corresponds to the effective area of pixels A1 of the first light modulation element. 11.
    Due to the manufacturing details and the details of the arrangement of the lens and other optical elements of the optical imaging system, the luminance modulated light coming from the effective surface of pixels A1 of the first element Light modulation 11 can be shifted from the effective area of pixels A2 of the second light modulation element 12, and penetrate it. The position of the effective surface of pixels A1 of the first light modulation element 11 is therefore displaced (modified) in the light incidence surface
    Cl more fixed in the modular pixel area
    B1 so as to correct the offset. Therefore, there is no need to maintain the manufacturing and layout accuracy of the lens and other optical elements of the optical imaging system, and high contrast can be obtained by means of simple electrical control.
    This configuration however causes the illumination light to penetrate at least a portion of pixels (which will be called, hereinafter peripheral pixels) of a peripheral surface (peripheral surface of pixels) Dl situated at the outside the effective area of pixels A1 in the modular area of pixels B1 of the first light modulation element 11. In other words, the light incidence surface C1 contains the peripheral pixels in addition to the pixels of the surface effective pixel Al.
    peripheral surface is arranged at the periphery of the effective pixel surface. When the illuminating light (reflected light not necessary) reflected on the peripheral pixels is projected onto the target plane by means of the second light modulation element 12 and the projection lens 10, the quality of the projected image becomes degraded.
    Consequently, the present embodiment controls the peripheral pixels of the first light modulation element 11 so that the illumination light penetrating and reflected on the peripheral pixels can be "unmodulated light (light to polarization P) ". Thus, the light reflected on the peripheral pixels passes through the first PBS 6 (polarization splitter or divider) and is returned to the light source unit side. In other words, the present embodiment controls the peripheral pixels of the first light modulation element 11 so that the illuminating light from the peripheral pixels does not reach the second light modulation element 12 (the surface pixels A2 and a part of the frame located outside of it). More particularly, the present embodiment controls the peripheral pixels so that the peripheral pixels can be in the black display state.
    This configuration makes it possible to solve the problems according to which, when the reflection type light modulation element is used as the first light modulation element 11, this causes projection of the reflected light which is not necessary. on the target plane and a decrease in image quality.
    A control device 20, such as a computer shown in FIG. 1, performs modulation control processing as a computer program in accordance with a flow diagram shown in FIG. 4.
    A memory, not shown, contains in position memory the effective surface of peripheral pixels pixels (surface Dl) light modulation [0030] At data of adjustment step 101 (“S” control device 20 of the effective surface
    Next, command 20 commands the element to extract pixels from memory in the factory.
    projector.
    Figure 4}, the pixel position data
    Al and device of the pixels of the effective surface of the light modulation element 11 of the first pixels al to modulate the luminance of the illumination light based on the signal f picture entered in response to the start trigger for the image projection. The controller 20 controls the peripheral pixels of the first light modulation element 11 so as to put them in the black display state. In addition, the controller 20 controls the pixels of the effective area of pixels A2 of the second light modulation element 12 pertaining to the image modulation of the light modulated in luminance.
    The control device 20 continues the step
    102 until the release of the image projection end trigger in step 103, and ends this processing 25 in response to the end trigger.
    A flowchart of Figure 5 shows an effective pixel surface adjustment processing intended to move the effective surface of pixels Al inside the modular surface B1 (light incidence surface
    C1) of the first light modulation element 11, as described above. The controller 20 as a modification device performs this processing via the computer program. The present embodiment describes a case in which the projector comprises an operating unit, not shown, through which a user can enter an instruction (adjustment instruction) intended to move the. effective area of Al pixels and a not shown shooting device which can capture the projected image.
    In step 201, the control device 20 5 determines whether the adjustment instruction has been entered from the operating unit. When the setting instruction has been entered, the flow goes to step 204, and when the setting instruction has not been entered, the flow goes to step 202.
    In step 202, the control device 20 captures the projected image via the camera. In the following step 203, the control device 20 compares the captured projected image and the image (input image) expressed by the signal with one another.
    1.5 of image entered, and determines the possible presence of a defect in the image entered near the upper, lower, left and right ends of the projected image. The controller 20 returns to step 201 in the absence of a fault, and proceeds to step 204 in the presence of the fault, so as to calculate the direction of movement and the amount of movement of the effective pixel area Al necessary to correct the fault.
    In step 204, the controller 20 moves the effective area of pixels A1 inside the modular area B1 of the first light modulation element 11 in accordance with the direction of movement and the amount of displacement corresponding to the adjustment instruction obtained in step 201 or calculated in step 203. Thereafter, the processing ends.
    The effective area of pixels A1 of the first light modulation element 11 can be similar to the effective area of pixels A2 of the second light modulation element 12. The similarity can be within a permissive range as well as be completely similar. Suppose that the effective area of pixels A1 of the first light modulation element 11 has a long side of xl and a short side of vl and that the effective area of pixels A2 of the second light modulation element 12 has a long side of x2 and a short side of y2. Full similarity is then satisfied when the expression yl / xl - y2 / x2 is satisfied. Permissible similarity is satisfied when the expression 0.8 (yl / xl) / (y2 / x2) 1.2 is satisfied. The effective area of pixels A1 of the first light modulation element 11 and the effective area of pixels A2 of the second light modulation element 12 may not be similar to each other.
    Using a liquid crystal panel for the first light modulation element 11 having a resolution lower than that of the second light modulation element 12, as in the present embodiment, allows to produce an electrical circuit substrate intended to drive the first light modulation element 11 of smaller size. In addition, the dark field matrix of the first light modulating element 11 may be less visible (practically not visible). On the other hand, as the resolution of the first light modulation element 11 increases, the position adjustment of the luminance modulated light may be finer of the effective pixel area A1 of the first light modulation element 11 to the effective area of pixels A2 of the second light modulation element 12. Resolutions in the longitudinal and horizontal directions (two orthogonal directions) of the first light modulation element 11 may correspond to a quarter, or more, of those second light modulation elements 12.
    Although FIG. 1 represents the second light modulation element 12 as being the only one, the real projector comprises three second light modulation elements 12 corresponding to the colors R (red), G (green) and B ( blue). The second PBS 9 serves as an optical separation and color combination system which directs the light R, the light G and the light B, as a flux of light modulated in luminance towards these three second modulation elements 12, and combines the with each other the R light, the G light and the B light as a light flux dpf image from the second three light modulation elements 12. Figure 3 shows an optical system for separating and combining representative colors.
    In Figure 3, a dichroic cross mirror (color separating element) 31 separates the light modulated in luminance (light with S polarization), reflected on the first PBS 6, in a first colored light (light B) and a second colored light (light G + light R). A polarization plate 38 is located between the first PBS 6 (or the first light modulation element 11) and the dichroic cross mirror 31, and allows light to pass through S polarization (and does not allow light to pass through P polarization ). This polarization plate 38 can use an absorption type polarization plate that absorbs P-polarized light, or a reflection type polarization plate that reflects P-polarized light, but the absorption-polarized plate allows to prevent the ghost caused by the reflection of P-polarized light
    The first colored light is reflected on a first mirror 32, and penetrates a second light modulation element 12B relating to light B by means of a second system
    8B of lenses and a second
    PBS 9B within the light B. The first light colorful (polar light ization P), in as long as light Image modulated by the second element modulation of light 12B, cross the second PBS 9B, is reflected on a catch dichroic me in cross 35, and is projected on
    the screen not shown by means of the projection lens 10.
    The second colored light passes through a second system 8Y of lenses belonging to the color Y, and is separated into a third colored light (light G) and a fourth colored light (light R) by a dichroic mirror 34. The third light colored penetrates a second light modulation element 12G pertaining to light G by means of a second PBS 9G pertaining to light G. The third colored light (P-polarized light), as image light modulated by the second light modulation element 12G, passes through the second PBS 9G, passes through the dichroic cross prism 35, and is projected onto the screen, not shown, by means of the projection lens 10.
    The fourth colored light penetrates a second light modulation element 12R falling under the light R by means of a second PBS 9R falling under the light R. The fourth colored light (P-polarized light), as image light modulated by the second light modulation element 12R, passes through the second PBS 9R, is reflected on the dichroic cross prism 35, and is projected onto the screen by the projection lens 10.
    Although the present embodiment describes the first light modulation element 11 as being the only one, it is possible to provide the first light modulation element for each of the colored light flows R, G and B.
    The first PBS 6 according to the present embodiment is a metal grid polarization beam splitter (WG-PBS), but it is possible to use a PBS of the prism type. The second PBS 9 according to the present embodiment is a PBS of the prism type but it can be WG-PBS.
    The optical illumination system according to the present embodiment comprises the first lens of the fly eye type 3 and the second lens of the fly eye type 4 but can use a rod integrator. In the present embodiment, the light modulation elements 11 and 12 use reflection type liquid crystal panels, but they can be transmission type liquid crystal panels or 5 digital mirror devices (DMD). .
    When the first light modulation element is a transmission type liquid crystal panel, a polarization plate can be provided in the optical path going from the first light modulation element to the second light modulation element. The controller can then control the effective pixels and the peripheral pixels so that the light from the effective pixels passes through the polarization plate and that the polarization plate 15 can absorb or reflect the light coming from the peripheral pixels.
    The first and second light modulation elements may not be of the same type, and, for example, the first light modulation element is a transmission type liquid crystal panel, and the second Light modulation can be a reflection type liquid crystal panel.
    According to the present embodiment, a relatively simple structure makes it possible to reduce the light reflected on the peripheral pixels of the first modulation element, of light and projected through the second light modulation element.
    OTHER EMBODIMENTS One or more embodiments of the present invention may also be implemented by a computer of a system or apparatus which extracts and executes instructions executable by computer (for example, a or more programs) stored on an information carrier (which may also be referred to in more detail as a "computer readable non-transient information carrier") to perform the functions of one or more of the embodiments described above and / or which comprises one or more circuits (for example, a specific integrated circuit (ASIC)) intended to ensure the functions of one or more of the embodiments described above, and by a method implemented by the system or device computer allowing, for example, to extract the computer-executable instructions from the information medium and to execute them, to ensure the f anointing of one or more of the embodiments described above and / or of controlling the one or more circuits to ensure the functions of one or more of the embodiments described above. The computer may include one or more processors (for example, a central processing unit (CPU), a microprocessor (MPU)) and may include a network of separate computers or separate processors for extracting and executing computer-executable instructions. Computer-executable instructions can. be supplied to the computer, for example, from a network or from an information medium. The information medium may include, for example, one or more of a hard disk, a random access memory (RAM), a read-only memory (ROM), a system memory device distributed computing, an optical disc (such as a compact disc (CD), a digital versatile disc (DVD), or a Blu-ray disc (BD) ™), a flash memory device, a card memory, and the like.
    Although the present invention has been described in connection with embodiments given by way of example, it should be understood that the invention is not limited to the exemplary embodiments described.
    权利要求:
    Claims (7)
    [1]
    1. An image projection apparatus, comprising: a first modulation element configured for a light source
    1b
    [2]
    2b a light (11) emitted from a second light; and a modulating second configured for module characterized in that the light is configured for on a modular surface of the first light, comprising a surface modulating the second light, first element receiving the first pixel (Bl) which can modular surface of effective modulating pixel (Al) which can first light and a peripheral pixel surface (Dl) disposed at the periphery effective pixel surface, the image projection apparatus a control device designed for peripheral surface of pixels light from the peripheral surface of pixels (Dl) does not reach the second light modulation element.
    2. The image projection apparatus of claim 1, further comprising an image forming system configured to image light on the second modulating element of 1 'comprising controlling the (Dl) so further in transmission ,
    The projection apparatus if the first image modulation crystal a polarization plate disposed on ui going from the first modulation element second light modulation element, and further comprising optical path of light to the polarization plate absorbs or reflects pixel light from the peripheral pixel surface.
    [3]
    4. An image projection apparatus according to claim 1, wherein the control device
    [4]
    5 controls the pixels of the peripheral surface of pixels so as to bring the peripheral pixels into a black display state.
    5. An image projection apparatus according to claim 1, wherein the first modulation element
    10 of light is a reflection type liquid crystal panel, the image projection apparatus further comprising a polarization splitter disposed on an optical path from the first light modulation element to the second light modulation element , and wherein the controller controls the peripheral pixels so that the light from the peripheral pixels is brought in a direction different from that of the second light modulating element through the polarization splitter.
    [5]
    6. Image projection apparatus according to. claim 1, further comprising a modification device configured to modify a position of the effective surface of pixels within the modular surface of
    25 pixels in the first light modulation element.
    [6]
    The image projection apparatus according to claim 1, wherein the first light modulating element has resolutions in two orthogonal directions which correspond to a quarter, or more, of
    30 those of the second light modulation element.
    [7]
    The image projection apparatus according to claim 1, wherein the effective pixel area of the first modulation element has a shape similar to an effective pixel area which modulates the second
    35 light in the second light modulation element.
    类似技术:
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    法律状态:
    2019-09-06| RS| Complete withdrawal|Effective date: 20190729 |
    优先权:
    申请号 | 申请日 | 专利标题
    JP2017154904A|JP2019032496A|2017-08-10|2017-08-10|Image projection device|
    JP2017154904|2017-08-10|
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