JP4050126B2 - Image projection display device - Google Patents

Description

[0001]
[Industrial application fields]
The present invention relates to an image projection display apparatus using an optical deflection array in which optical deflection elements capable of changing the direction of outgoing light with respect to incident light are arranged in a one-dimensional or two-dimensional array.
[0002]
[Prior art]
A light deflection element that deflects incident light in a plurality of predetermined directions and a light deflection array in which a plurality of light deflection elements are arranged in a one-dimensional or two-dimensional array are known (see, for example, Patent Document 1). . Also, image display apparatuses using such an optical deflection array are described in Japanese Patent Application Nos. 2001-349415, 2002-95973, 2002-178216, and the like.
[0003]
The optical deflection elements shown in the above documents include elements that can deflect light in two directions around one axis, elements that can deflect in more directions around two or more axes, and the like. is there. As an optical deflection array used as an image display device, an array using a uniaxial optical deflection element is sufficient for monochromatic display. However, in order to display a color image, synthesis of three primary colors is necessary. You have to devise. In the above-mentioned documents and the like, a device that switches a color filter placed immediately before a white light source at high speed by rotation or the like is described.
[0004]
FIG. 9 is a schematic diagram showing a conventional example of a color image display device.
In the figure, W is a white light source, F is a rotating disk-shaped color filter group, AR is a light deflection array of uniaxial bi-directional deflection, M is a microlens array, L1 and L2 are projection lens groups, AP is an aperture, and S Indicates a screen respectively.
[0005]
It is assumed that the light beam emitted from the white light source passes through one of the filters in the filter group F that switches in time sequence, for example, the red filter FR. The luminous flux becomes red light R and enters the combination of the microlens array M and the light deflection array AR. The light beam is made substantially parallel light by each microlens and enters each light deflection element of the light deflection array. At this time, the color information corresponding to the red image is input to the optical deflection array, and one of the two deflection directions is assigned to the individual optical deflection elements with respect to the presence of the color information. The other deflection direction is assigned so that the deflection directions are different from each other. The presence of the color information is simply referred to as color information, and the absence of color information is referred to as off-information for convenience.
[0006]
The light reflected in the direction deflected by the color information signal again passes through the microlens array M and then exits in the direction of the projection lens L1, and the image shown on the light deflection array AR is converted into the projection lens L1, An image is formed on the screen S by L2. The light reflected in the direction deflected by the off-information signal again passes through the microlens and then exits in a direction not shown but does not enter the projection lens, so that it does not reach the screen S by the absorption shielding plate. Configured.
When the three colors are projected onto the screen in time sequence at high speed, when viewed with the human eye, the image that has been color-separated by the afterimage cannot be seen individually, but an image synthesized as a color image can be seen.
[0007]
With this configuration, it is possible to form a color image, but color mixing occurs during the switching of the filter colors, so that the image cannot be displayed. Therefore, the time for the boundary portion of the filter to pass through the beam cross section must be made as short as possible, and the time for the real portion of the filter to pass through the beam cross section must be made as long as possible. For this purpose, the cross section of the light beam must be made sufficiently smaller than the circumferential length of the filter. If the cross section of the light beam is reduced, the amount of light is reduced, which is not preferable. If the cross section of the light beam is large, the disk shape of the filter must be increased correspondingly, leading to an increase in the size of the apparatus.
[0008]
In order to display a color image without using a rotating filter, an image display device using a plurality of light deflection elements has been put into practical use (for example, see Non-Patent Document 1). These are excellent in that a high-definition image can be displayed. However, it is not preferable to use a plurality of expensive optical deflection elements because of the high cost.
In order to display a color image with only one light deflection element without using a rotating filter, the deflection direction for the three primary colors and one direction for off (black) information, at least four deflection directions. An array using an optical deflection element having
The outline of the optical deflection element and the optical deflection array will be described below.
[0009]
FIG. 10 is a plan view showing an example of an optical deflecting element having two biaxial and four deflecting directions.
11 is a cross-sectional view of the optical deflection element shown in FIG.
FIG. 12 is a plan view showing an example of an optical deflecting element having deflection directions of four axes and eight directions.
In the figure, reference numeral 1 denotes a light reflecting surface, 2 denotes a plate-like member, 3 denotes a substrate, 4 denotes a fulcrum member, and 5 denotes a regulating member.
In order to simplify the description, a biaxial deflection element will be described below as an example.
[0010]
The plate-like member 2 itself is formed of an insulating member, but the light reflecting surface 1 has conductivity. The fulcrum member 4 is on the upper surface of the square substrate 3 and has a quadrangular pyramid shape with a bottom surface slightly smaller than the upper surface. The vicinity of the apex of the quadrangular pyramid is formed to be conductive and is configured to conduct with the conductive portion on the plate-like member 2. The four inclined surfaces of the quadrangular pyramid are formed with electrodes 6a1 to 6a4 that are insulated from each other and independent of the conductive portion near the apex. The plate-like member 2 can move in any direction within the space formed by the apex of the fulcrum member 4 and the four restricting members 5.
[0011]
When a predetermined level of potential difference is applied between any one electrode 6 on the slope of the quadrangular pyramid and the plate-like member 2, the plate-like member 2 is attracted to the slope and tilted in the direction of the slope. If the electrode that gives the potential difference is changed, the direction in which the plate-like member 2 is tilted changes accordingly. Therefore, when light is applied to the light reflecting surface 1 from an arbitrary direction, the light reflection direction is deflected in four directions according to the inclination direction of the plate-like member 2. If light is incident from the direction of the symmetry axis of the quadrangular pyramid, the reflected light can be emitted in four symmetric directions with the incident light as the center.
[0012]
The optical deflection array is formed by closely arranging the optical deflection elements as described above in the vertical and horizontal directions, and the number of the optical deflection elements arranged in the vertical and horizontal directions is determined according to the number of vertical and horizontal pixels necessary for image display. When parallel light is applied to the entire optical deflection array, when all the optical deflection elements are deflected in the same direction, the reflected light beam becomes parallel light having a cross section substantially the same type as the optical deflection array, and proceeds in a predetermined direction. . However, since the light reflecting surface 1 has an ineffective area regarding reflection between adjacent elements, the light flux is an aggregate of reflected light for each element. Assuming that a screen parallel to the surface of the light deflection array is placed at some distance from the light deflection array, and the deflection directions of the light deflection elements are simultaneously aligned to any deflection direction and switched sequentially, In this case, four light beam sections separated from each other of the same type as the optical deflection array are observed in sequence.
[0013]
A color filter for three primary colors is applied to three of the four separated light beams, and the remaining one is shielded from light. By deflecting the light deflection elements individually according to the presence or absence of the three primary color separation data of the image instead of the deflection of the light deflection array as a whole, the separated light flux becomes a single color image carrying the respective color information. Therefore, if these single color images can be successfully combined into one image, it can be displayed as a color image.
Even if a four-axis eight-direction deflection element is used, an image display apparatus substantially similar to the above can be obtained by utilizing the four-direction deflection.
[0014]
[Patent Document 1]
JP-A-6-138403 (paragraph 0010, FIGS. 1 and 3)
[Non-Patent Document 1]
Optical Engineering Vol.39 No.7 July 2000 p. 1802-1807
[0015]
[Problems to be solved by the invention]
Although the image display apparatus disclosed in the above document can display a high-definition image, the cost is unavoidable.
An object of the present invention is to provide a specific configuration of an optical system that can be used as a high-definition image display device without being very expensive.
[0016]
[Means for Solving the Problems]
According to the first aspect of the present invention, there is provided a single light deflection array in which a plurality of light deflection elements having four or more deflection directions are arranged in a one-dimensional or two-dimensional array, 1 white A light source; Includes three projection lenses corresponding to the three primary colors of image information, each optical axis being parallel to the normal to the plane of the light deflection array An image display device comprising a projection optical system and an image display unit, The light deflection array and the image display unit are arranged to be optically conjugate with each other with respect to the projection optical system; Of the four or more deflection directions, there are four deflection directions. Said Assign color information and off information for the three primary colors The light beam from the illumination light source is deflected time-sequentially in a deflection direction corresponding to each of the color information of the three primary colors by a switching cycle that is observed as a full color by the afterimage phenomenon of the human eye, and then the white color The light is passed through a color filter corresponding to each of the color information of the three primary colors, and is superimposed on the surface of the image display unit by the action of the projection optical system. It is characterized by that.
[0018]
Claim 2 In the invention of Claim 1 In the image projection display device described in (1), the projection optical system further includes a first field lens that transmits all light beams including the color information by deflection of the light deflection array, and substantially the same as the first field lens. The optical system using the first field lens and the second field lens includes a second field lens having a size. In the middle of both lenses, the central light beam of each color image is parallel to each other. The array and the image display unit are arranged so as to be optically conjugate with each other, and each of the three projection lenses includes the light deflection array and the image display unit in combination with the two field lenses. They are arranged so as to be optically conjugate with each other.
[0019]
Claim 3 In the invention of Claim 1 In the image projection display device described in (1), the projection optical system has a first prism in front of each of the three projection lenses and a second prism in the rear, and is separated from each other by deflection of the light deflection array. A light beam passing through the center of the light beam including the color information traveling in the direction is made parallel to the normal of the surface of the light deflection array by the first prism, and passes through the center of the light beam after passing through the projection lens. The direction of action is set by the second prism so as to go to the display center of the image display unit, and each of the projection lenses is combined with the two prisms, and the light deflection array and the The image display unit is configured to be optically conjugate with each other.
Claim 4 In the invention of Claim 3 In the image projection display device described in (1), the first and second prisms use prisms whose desired deviation angle is the maximum deviation angle, and light rays passing through the center of the light beam are incident on the surfaces of the prisms. And the emission angles emitted from the opposite surfaces of the prisms are set to be substantially equal to each other.
[0020]
Claim 5 In the invention of Claim 1 In the image projection display device described in the above, after the projection optical system transmits the light beam including the color information by the deflection of the light deflection array to each of the three projection lenses corresponding to the color information, A semi-transparent mirror is installed so as to be approximately 45 degrees with respect to the surface of the light deflection array, and a retroreflecting light reflecting member that individually reflects the light beam after transmission through the semi-transparent mirror is provided for each light beam. The optical deflection array and the image display unit are set so as to be optically conjugate with each other.
Claim 6 In the invention of Claim 5 In the image projection display device described in (1), the retroreflecting light reflecting member is a single corner cube reflector having an opening for receiving the entire light beam transmitted through the projection lens.
[0021]
Claim 7 In the invention of claim 1, 6 In the image projection display device according to any one of the above, the white light emitted from the light source is shaped into a parallel light beam whose cross section is larger than the surface shape of the light deflection array.
Claim 8 In the invention of claim 1, 7 In the image projection display device according to any one of the above, the light beam deflected by carrying the color information by the light deflection array passes through any one of the projection lenses, reaches the image display unit, and its optical path Among these, the color filter corresponding to the color information is passed through any one of the ranges that do not overlap with the light flux carrying other color information.
[0022]
Claim 9 In the invention of Claim 8 In the image projection display device described in (1), the color filter is provided in the projection lens or on the front or rear surface of the projection lens.
Claim 10 In the invention of Claim 8 In the image projection display device described above, the color filter is provided in an optical element other than the projection lens.
Claim 11 In the invention of claim 1, 10 In the image projection display device according to any one of the above, the illumination light beam from the light source is projected perpendicularly to the surface of the light deflection array via a reflecting mirror from a direction deviating from the normal of the surface of the light deflection array. It is characterized by being illuminated.
[0025]
Claim 12 In the invention of claim 1, 16 In the image projection display device according to any one of the above, the image information to be projected is converted into grayscale by changing the time to stop in the reflection direction corresponding to each color information of each light deflection element included in the light deflection array. It is characterized by having a display.
Claim 13 In the invention of Claim 12 In the image projection display device described in 1), the maximum time held in each reflection direction corresponding to the three primary colors of each light deflection element is about one third of the display time of one frame for displaying an image. It is characterized by being.
[0026]
Claim 14 In the invention of Claim 12 In the image projection display device described in (1), the maximum time of the time held in each reflection direction corresponding to the three primary colors of each of the light deflecting elements is substantially equal to the display time of one frame for displaying an image, corresponding to three colors. The time added is set to be shorter than the display time of one frame.
Claim 15 In the invention of Claim 14 In the image projection display device described in 1), when the time obtained by adding the times for the three colors exceeds the display time for one frame, the sum of the times for the three colors without changing the gradation ratio of the three colors. Is automatically adjusted so that is substantially equal to the display time of one frame.
[0027]
【Example】
The present invention will be described below with reference to examples.
FIG. 1 is a side view for explaining an outline of an optical system according to an embodiment of the present invention.
FIG. 2 is a partial perspective view showing the state of the light flux from the light source.
In both figures, reference numeral 10 denotes an optical deflection array, 11 denotes a first field lens, 12 denotes a projection lens, 13 denotes a second field lens, 14 denotes an image display unit, 15 denotes a light source, 16 denotes a light beam shaping lens, and 17 denotes a plane. Reflector, L is a light beam, and O is the optical axis of the entire optical system. In addition, R, G, B, and off indicate members or portions that are related to the color information of the three primary colors red, green, and blue and off information in addition to other symbols.
In FIG. 1, a light source system for allowing parallel light beams to enter the optical deflection array is omitted in order to avoid complication of the drawing. In FIG. 2, the light flux up to the surface 11a of the first field lens is shown, and the light flux after transmission is omitted.
[0028]
The incident light beam is changed from the light source 15 shown in FIG. 2 into a parallel light beam L by a light beam shaping lens 16 usually called a condenser lens, changed in direction by a plane reflecting mirror 17, and set perpendicular to the surface of the light deflection array. It is configured to enter along the optical axis O. The shape of the light beam is adjusted by the light shielding mask 16a so that the cross section of the light beam L is substantially the same as the shape of the effective portion of the light deflection array and is slightly larger. The light source 15 is a white light source such as a xenon lamp, a halogen lamp, or a mercury lamp.
However, it is not an essential requirement that the incident light beam from the light source is incident on the surface of the light deflection array 10 perpendicularly. In the case of normal incidence, the deflection angles are equal in all the deflection directions, so that the design of the optical system is easy, and other than normal incidence can be adopted as necessary.
[0029]
The light beam L incident on the light deflection array 10 is deflected according to image information for each color, that is, color information. For example, the reflected light becomes a light beam LR for a predetermined time. When the light beam LR is incident on the surface 11 a of the first field lens 11, the light beam LR is refracted and emitted so that its central light is parallel to the optical axis O. Further, the light beam LR is placed in the vicinity of the first field lens 11, and its optical axis is transmitted through the projection lens 12R parallel to the normal to the surface of the light deflection array 10 to receive an image forming action. The light is incident on the second field lens 13 having the same size as the field lens 11. The light flux LR is refracted by the second field lens so that the central light thereof is directed toward the display center 14 a of the image display unit 14.
[0030]
Note that the lines indicating the luminous fluxes in the figure do not represent the light rays by the ray tracing, but merely indicate the limits of the luminous flux. The light beam from the light deflection array to the projection lens is a parallel light beam, but the light beam exiting the projection lens travels toward the conjugate position on the image display unit corresponding to the reflection point of the light deflection array. As can be seen, there can be rays of any angle within the limits of the luminous flux.
[0031]
The image forming action of the projection lens 12R is set so that the light deflection array 10 forms an image just on the image display unit 14 as a comprehensive action with the front and rear field lenses. In other words, the projection lens 12R is arranged such that the light deflection array 10 and the image display unit 14 are optically conjugate with each other in combination with the two field lenses 11 and 13.
[0032]
Even if the light beam LR bears color information, it does not become a color image as long as the light emitted from the white light source is used as it is. In the present embodiment, a color filter F that changes white light into three primary colors is provided in any of the optical elements included in the optical system from the first field lens to the second field lens. The installation position of the color filter F may be the smallest in the projection lens. However, in consideration of compatibility, it is preferable to install the color filter F on either the front surface or the rear surface of the projection lens. However, when the luminous flux before and after the incidence of the projection lens is not so large as in the present optical system, for example, even if the color filter F is provided in close contact with the first or second field lens, the filter size is particularly increased. There is no. FIG. 1 shows an example in which the color filter FR is installed on the incident surface 11a of the first field lens. The color filter F is provided close to these optical elements because it is easy to mount. The installation position is a position where the light beam does not overlap with the light beam carrying other color information. Adopt anywhere.
[0033]
During the next predetermined time, the light deflection array is deflected by the next color information to become, for example, a light beam LG. The central beam of the light beam LG appears to coincide with the optical axis O in FIG. 1, but as seen from the perspective view of FIG. Yes. Therefore, the subsequent effect of the light beam LG from the optical system is exactly the same as that of the light beam LR except for the difference between the side view and the plan view. Therefore, the light beam LG is imaged and displayed with the center of the light beam aligned with the display center 14a of the image display unit. Further, the light beam LB is generated for the next predetermined time, and the light beam center coincides with the display center 14a of the image display unit in the same manner as described above.
In other words, if the first and second field lenses are viewed as one optical system, the optical deflection array 10 and the image display unit 14 work so as to be optically conjugate with each other.
[0034]
In the above description, the light beams LR, LG, and LB are only shown as the light beams carrying the color information. However, the color information is input as binary information with and without a color here. Therefore, the light beam includes only the light beam obtained according to the deflection direction when there is a color. When there is no color information, that is, off information, the deflection direction of the light deflection element is the direction of the light beam Loff in FIG. In addition, the deflection direction of the off information is common to the three primary colors. Since the light flux Loff is unnecessary for image display, the light flux Loff is shielded by a light shielding member (not shown) at a position that does not affect other effective light flux, for example, on the incident surface 11a of the first field lens 11. .
[0035]
By the way, as long as there is no image accumulating action in the image display unit, when the image by the light beam LG is displayed, the image by the light beam LR disappears. Similarly, when the image by the light beam LB is displayed, the image by the light beam LG has already disappeared. That is, since only three color images are displayed in time sequence, no full color image exists at any moment. However, such an image is also observed as a full color due to the afterimage phenomenon as long as it is viewed by human eyes if the switching cycle is sufficiently short. This is almost the same phenomenon as when the sesame seeds that are painted in the three primary colors are rotated, if the rotation speed is fast, the individual tops look gray without feeling the individual colors.
[0036]
FIG. 3 is a side view for explaining the outline of an optical system according to another embodiment of the present invention. In the figure, reference numeral 21 denotes a first prism, and 23 denotes a second prism. 1 and 2 indicate parts having the same function.
Since this embodiment is basically very similar to the previous embodiment, only the light beam LR will be described.
[0037]
The light beam LR is incident on the first prism 21R and receives a declination effect unique to the prism, so that the light beam at the center of the light beam becomes parallel to the optical axis O. The light beam LR receives the image forming action of the projection lens 12R and enters the second prism 23R after being emitted. Here, the light beam passing through the center of the light beam is refracted toward the display center 14 a of the image display unit 14. The image displayed on the optical deflection array 10 is imaged on the image display unit 14 by the imaging action of the projection lens 12R.
[0038]
The prism is an optical element having a refractive action only in one direction. That direction is called the action direction for convenience. Even if the prisms have the same apex angle, if the incident angle of the incident light beam is different, the angle difference from the emission angle, that is, the declination angle is slightly different. When the angle of the light beam with respect to the normal of each of the incident surface and the outgoing surface, that is, the incident angle and the outgoing angle are equal, the deflection angle becomes maximum. At this time, the influence of the prism installation error on the deflection angle is the least. Therefore, it is best to use a prism having an apex angle such that the desired declination becomes the maximum declination. The desired declination is that the central beam of the light beam between both prisms is parallel to the optical axis O. Therefore, in FIG. 3, the first prism is the angle formed by the reflected light beam from the light deflection array and the optical axis O. In terms of the second prism, it is the angle β formed by the light beam at the center of the light beam reaching the display center 14a after passing through the prism and the optical axis O.
[0039]
FIG. 4 is a side view for explaining the outline of an optical system according to still another embodiment of the present invention.
In the figure, reference numeral 18 denotes a semi-transparent mirror, and 19 denotes a corner cube reflector as a retroreflecting light reflecting member.
The retroreflective member generally refers to a member having a property of emitting an incident light beam in a direction parallel to the incident light beam after receiving some reflection effect. Glass bead type and corner cube type are known.
[0040]
The refractive index of the glass bead type is selected so that the incident parallel light beam is subjected to a lens action on the incident surface of the glass bead and is condensed on the opposite surface. The opposite surface is given total reflection, and the light beam can be swapped up and down, left and right, so that it follows almost the same optical path, the same incident surface becomes the exit surface, and it becomes the original parallel light beam. Go backwards.
[0041]
The corner cube type has a shape in which three surfaces including one vertex of a cube are cut into a triangular pyramid shape, and the inside of the three surfaces is a reflecting mirror. When a light beam is incident from the bottom side of the triangular pyramid, the light beam is reflected three-dimensionally by hitting the mirror surface once or three times depending on the incident position and angle, and is generally incident from an exit point different from the incident point. Going out parallel to the rays. Therefore, if a parallel light beam is incident from the bottom side, the emitted light also becomes a parallel light beam and exits in the original direction.
[0042]
The light beam LR deflected by the optical deflection array 10 directly enters the projection lens 12R. The light beam LR imaged by the projection lens 12R reaches the semi-transparent mirror 18, and half of the amount of light is reflected and lost, and the remaining half is transmitted. When the transmitted light enters the corner cube reflector 19R, each light beam in the light beam is reflected parallel to the incident angle. As described above, the light beam that has passed through the projection lens exits from an exit point that is different from the incident point, and can have any angle within the limit of the light beam. Therefore, the limit of the light beam after exiting the corner cube reflector 19R. Extends beyond the limit of the luminous flux before incidence. The corner cube reflector has a three-dimensional structure, but is represented by a simple right-angle cross section in the figure.
[0043]
The light beam that has exited the corner cube reflector again reaches the semi-transparent mirror 18, where a further half of the light amount is transmitted and lost, and the remaining half is reflected and reflected on the surface of the image display unit 14. Form an image. At this time, the light beam passing through the center of the light beam inevitably reaches the display center 14a of the image display unit. The display center 14 a has a mirror image relationship with the center of the light deflection array with respect to the semi-transparent mirror 18.
Thus, in the case of the present embodiment, only a quarter of the light beam reflected by the light deflection array 10 contributes to the image formation.
The light beams LG and LB carrying other color information are also superimposed on the surface of the image display unit 14 with the center aligned in the same manner.
[0044]
FIG. 5 is a perspective view of a part of a light source system for explaining still another embodiment of the present invention.
FIG. 6 is a side view for explaining the outline of the optical system of the embodiment shown in FIG.
In both figures, the symbols r, g, and b indicate that they are individually associated with the three colors in addition to the symbols, as in the previous R, G, and B.
In the present embodiment, three independent light sources are used corresponding to the three primary colors. FIG. 5 shows only one of the three light sources to avoid complexity.
[0045]
In FIG. 6, the condensing lens 16G is placed at a position substantially the same as the position where the light beam LG in FIG. 2 is incident on the first field lens 11a, and the light source 15G has a shape in which the divergent light beam reverses the light beam LG by the condensing lens 16G. Is arranged so as to form an illumination light beam LG ′.
The illumination light beam LG ′ is green light of three primary colors. The light source itself may develop a green color, or a white color light source may be covered with a green color filter. The position of the color filter may be just before the light source or before or after the condenser lens. The color filter may be placed anywhere as long as it does not overlap with other monochromatic light.
[0046]
With this configuration, when each element of the light deflection array is deflected in FIG. 5 in the same direction as that in which the light beam LG is formed in FIG. 2, the illumination light beam LG ′ is perpendicular to the surface of the light deflection array 10. Is deflected as a light beam L ′ in FIG. In the side view of FIG. 6, since the illumination light beam LG ′ and the light beam L ′ overlap, the light source 15G is omitted, but the light source 15R, the illumination light beam LR ′, and the light beam L ′ have the same relationship.
The light beam L ′ enters the opening 12a of the projection lens 12, and the emitted light forms an image on the surface of the image display unit 14 so that the light beam passing through the center of the light beam coincides with the display center 14a of the image display unit 14. Then, the image having the green color information shown in the light deflection array 10 is displayed.
[0047]
Similarly, when the other primary colors of the three primary colors, that is, red and blue are configured in the same manner, the illumination beams LR ′ and LB ′ of the respective single colors are light beams carrying corresponding color information by the light deflection array 10. Are coincident with the luminous flux L ′. Therefore, the image display unit 14 has no worries about errors, and the three color images coincide with each other and are superimposed.
[0048]
If the deflection direction of the light deflection array 10 is all directed to the direction corresponding to the red color information, the illumination light beam LR ′ is deflected in the direction of the light beam L ′, but the illumination light beams LG ′ and LB ′ are completely different from each other. Deflected in the direction. The illumination light beam LG ′ will be described.
The deflection surface of the optical deflection element is a plane mirror. The plane mirror of each element has its normal line N oriented in a direction that bisects the internal angle formed by the incident light beam and the outgoing light beam, and the plane mirror reflects the light beam in a symmetric direction with respect to the normal line. Therefore, under the above conditions, the illumination light beam LG ′ is a reflected light beam that is symmetric with respect to a normal line Nr described later, as indicated by LG′r in FIG.
[0049]
In FIG. 5, the light beam LG′r apparently overlaps with the light beam L ′ due to the drawing angle relationship, but both have different emission directions from the light deflection array 10.
Since the optical deflection array is an assembly of optical deflection elements, individual normal lines cannot be displayed, and therefore only one Nr is typically shown at the center of the optical deflection array. The same applies to the following.
[0050]
If all the deflection directions of the light deflection array 10 are directed to the direction corresponding to the blue color information, the illumination light beam LG ′ is related to the normal line Nb as indicated by LG′b in FIG. 5 for the same reason as described above. It becomes a symmetrical reflected light beam. Since these light beams that are ineffective for image display do not enter the projection lens and become so-called stray light, it may be devised to absorb or block as necessary.
[0051]
When displaying each color information, the light deflection element containing the off information tilts the deflection surface in the same direction as when the light beam Loff is formed in FIG. At this time, since the normal line of the plane mirror of the light deflection element is directed in the Noff direction, the illumination light beam LG ′ becomes a light beam LG′off by the light deflection element and does not enter the projection lens. Pixels corresponding to are displayed in black.
[0052]
Although the illumination light beam LG ′ has been described above, the other illumination light beams are exactly the same although not shown except for LR′b in FIG. As shown in FIG. 5, LG'b and LR'off overlap at substantially the same light beam position.
Therefore, since each monochromatic light source does not interfere with each other, it can continue to illuminate even when other color information is displayed.
[0053]
FIG. 7 is a time chart showing an embodiment in which the reflection direction of the light reflecting surface of each light deflection element is switched in color sequence.
In the figure, the symbol t represents time, t _R , T _G , T _B Indicates the holding time assigned to each of the three colors.
Although the light deflection element has a function of switching the light reflection direction, it cannot modulate the intensity of the reflected light. In order to display a color image, halftone display is indispensable. Therefore, a method called PWM is used in which reflected light is time-controlled to represent a halftone by a change in energy amount of time integration (for example, Proceedinng of the IEEE, Vol. 86, No. 8, August 1998, p1700).
[0054]
In this embodiment, the above-described PWM technology is applied to various image projection display devices as described above, and the image is switched at a rate of 60 frames per second, and all the light deflection elements can be individually controlled. And The display time for one frame of the image is approximately 16.67 milliseconds. The display time assigned to the three colors is 5 milliseconds, which is about one third of the display time of one frame, and a reset time of about 1.67 milliseconds is provided for each frame. However, the reset time can be omitted and the time can be assigned to each color.
[0055]
The number of gradations to be expressed per color is determined to be, for example, 4 gradations or 8 gradations, and the above 5 milliseconds can be divided in time according to the number of gradations. In addition, the time for holding each light deflection element in a predetermined deflection direction is varied. Depending on the switching time when deflecting the optical deflection element, a maximum of 256 gradations can be displayed.
For example, in the light deflection element corresponding to the pixel A1, about one half of the maximum display time is held in the deflection direction of each color display for all three colors, and other times are held in the direction of off information. Yes. Therefore, at this time, the pixel appears to the observer as an intermediate level of white, that is, gray.
Regarding the pixel A2, the deflection holding time in the red display direction is longer than that of the other two colors. Also, blue is slightly longer than green. Therefore, at this time, this pixel appears to the observer as purpleish pink.
[0056]
Similarly, regarding the pixel A3, the deflection holding time in the red display direction is the maximum, and the deflection holding time in the green display direction is short. At this time, this pixel appears to the observer as a strong reddish orange color.
For the pixel A4, only the blue direction is deflected and held. At this time, this pixel looks blue to the observer.
In this way, different colors can be expressed in each pixel.
[0057]
FIG. 8 is a time chart showing another embodiment.
In this embodiment, the maximum holding time for each color is made substantially equal to the display time T for one frame. The reason why they are almost equal is that when the reset time is taken for each frame, the time allocated to the maximum holding time is slightly smaller than the display time T of one frame. The display time of the three colors is displayed as it is when the sum of the respective holding times is smaller than the display time T of one frame, and when the sum is exceeded, the display time of the three colors is maintained while maintaining the ratio of the three colors. Automatic adjustment is performed so that the total holding time is approximately equal to the time T of one frame. That is, the holding time corresponding to each color is set to t _R , T _G , T _B Then, the sum of the times t _R + t _G + t _B If it is = <T, it is displayed as it is. t _R + t _G + t _B If> T, let k be a constant,
t _R '= K · t _R , T _G '= K · t _G , T _B '= K · t _B Replace with
t _R '+ t _G '+ t _B K is calculated and automatically adjusted so that '= T.
[0058]
However, when the display as described above is performed, the gradation property of a single color can be increased, but the gradation ratio of the three colors is the same, and t _R + t _G + t _B If> T, all t will be whatever the sum _R '+ t _G '+ t _B Since '= T will be the same value, the hue will not change, but the gradation on the brighter side cannot be expressed well. Therefore, this embodiment is suitable for displaying an image with very little gradation, for example, an image such as a line drawing.
[0059]
【The invention's effect】
Claim 1 11 According to the invention described in (4), a specific configuration of an image projection display device using an optical deflection array can be provided.
Claims 12 to 15 According to the invention described in (1), the image projection display device can perform halftone display using an optical deflection array that can only perform binary display.
[Brief description of the drawings]
FIG. 1 is a side view for explaining an outline of an optical system according to an embodiment of the present invention.
FIG. 2 is a partial perspective view showing a state of a light beam from a light source.
FIG. 3 is a side view for explaining an outline of an optical system according to another embodiment of the present invention.
FIG. 4 is a side view for explaining an outline of an optical system according to still another embodiment of the present invention.
FIG. 5 is a perspective view of a part of a light source system for explaining still another embodiment of the present invention.
6 is a side view for explaining the outline of the optical system of the embodiment shown in FIG. 5; FIG.
FIG. 7 is a time chart showing an embodiment in which the reflection direction of the light reflection surface of each light deflection element is switched in color sequence.
FIG. 8 is a time chart showing another embodiment.
FIG. 9 is a schematic configuration diagram illustrating a conventional example of a color image display device.
FIG. 10 is a plan view showing an example of an optical deflection element having deflection directions in two axes and four directions.
11 is a cross-sectional view taken along the line AA ′ of the optical deflection element shown in FIG.
FIG. 12 is a plan view showing an example of an optical deflecting element having deflection directions of four axes and eight directions.
[Explanation of symbols]
10 Light deflection array
11 First field lens
12 Projection lens
13 Second field lens
14 Image display
15 Light source
16 Condensing lens
18 Semi-transparent mirror
19 Retroreflective member
21 First prism
23 Second prism

Claims (15)

Corresponding to one light deflection array in which a plurality of light deflection elements having four or more deflection directions are arranged in a one-dimensional or two-dimensional array, one white light source for illumination, and three primary colors of image information, An image display device comprising: a projection optical system including three projection lenses each having an optical axis parallel to a normal to the surface of the light deflection array; and an image display unit,
The light deflection array and the image display unit are arranged to be optically conjugate with each other with respect to the projection optical system;
The assignment of color information and off information of each of the three primary colors in the four directions of the deflection direction of the four or more directions of the deflection direction
The light beam from the illumination light source is deflected time-sequentially in a deflection direction corresponding to each of the color information of the three primary colors by a switching period that is observed as a full color by the afterimage phenomenon of the human eye, and then the white color The light is passed through a color filter corresponding to each of the color information of the three primary colors, and is superposed with the center on the surface of the image display unit by the action of the projection optical system. An image projection display device. 2. The image projection display device according to claim 1, wherein the projection optical system further includes a first field lens that transmits all light beams including the color information by deflection of the light deflection array, and the first field lens. 3. A second field lens of approximately the same size as the optical system of the first field lens and the second field lens, in the middle of both lenses, the central ray of each color image is parallel to each other, The light deflection array and the image display unit are optically conjugate with each other, and each of the three projection lenses is combined with the two field lenses, and the light deflection array and the image display unit. Are arranged so as to be optically conjugate with each other . 2. The image projection display device according to claim 1 , wherein the projection optical system includes a first prism in front of each of the three projection lenses and a second prism in the rear, and the deflection of the optical deflection array. The light beam passing through the center of the light beam including the color information traveling in the direction away from each other is made parallel to the normal of the surface of the light deflection array by the first prism, and the light beam after passing through the projection lens The direction of action is set so that a light beam passing through the center is directed to the display center of the image display unit by the second prism, and each of the projection lenses is combined with the two prisms to generate the light deflection. image projection display apparatus characterized by the array and the image display unit is arranged so as to be optically conjugate to each other. 4. The image projection display device according to claim 3 , wherein the first and second prisms use a prism having a desired deflection angle having a maximum deflection angle, and a light beam passing through the center of the light beam is a surface of each prism. An image projection display device characterized in that the incident angle with respect to the light beam and the outgoing angle emitted from the opposite surface of the prism are substantially equal . 2. The image projection display device according to claim 1 , wherein the projection optical system transmits a light beam including the color information by deflection of the light deflection array to each of three projection lenses corresponding to the color information. Then, a semi-transparent mirror is installed so as to be approximately 45 degrees with respect to the surface of the light deflection array, and a retroreflecting light reflecting member for individually reflecting the light beam after passing through the semi-transparent mirror is provided for each light beam, and the projection lens The image projection display device is characterized in that the light deflection array and the image display unit are optically conjugate with each other . 6. The image projection display device according to claim 5 , wherein the retroreflecting light reflecting member is a single corner cube reflector having an opening for receiving the entire light beam transmitted through the projection lens. apparatus. 7. The image projection display device according to claim 1 , wherein the white light emitted from the light source is shaped into a parallel light beam whose cross section is larger than the surface shape of the light deflection array. Image projection display device. 8. The image projection display device according to claim 1, wherein the light beam deflected by carrying the color information by the light deflection array passes through any one of the projection lenses, and the image display unit. An image projection display device characterized by passing through a color filter corresponding to the color information in any one of the ranges that do not overlap with the light flux carrying other color information in the optical path . 9. The image projection display device according to claim 8 , wherein the color filter is provided in the projection lens or on a front surface or a rear surface of the projection lens . 9. The image projection display device according to claim 8 , wherein the color filter is provided in an optical element other than the projection lens. The image projection display device according to any one of claims 1 to 10 , wherein an illumination light beam from the light source is transmitted through a reflecting mirror from a direction deviating from a normal line of the surface of the light deflection array. An image projection display device characterized by being projected perpendicularly to a surface . 12. The image projection display device according to claim 1 , wherein the projection is performed by changing a stop time in a reflection direction corresponding to each color information of each light deflection element included in the light deflection array. An image projection display device that displays image information with gradation . 13. The image projection display device according to claim 12 , wherein the maximum time of the time held in each reflection direction corresponding to the three primary colors of each light deflection element is about 3 minutes for each display time of one frame for displaying an image. image projection display apparatus which is a one. 13. The image projection display device according to claim 12 , wherein a maximum time of time held in each reflection direction corresponding to the three primary colors of each light deflection element is substantially equal to a display time of one frame for displaying an image. An image projection display device characterized in that the time obtained by adding the time for colors is equal to or shorter than the display time of one frame . 15. The image projection display device according to claim 14 , wherein a time obtained by adding the time for the three colors exceeds a display time for one frame, and the ratio for the three colors is not changed without changing the gradation ratio of the three colors. image projection display equipment, characterized in that the sum of the time is automatically adjusted so that approximately equal to the display time of one frame.

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