JP2004309786A - Light source device and display device using same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a light source device capable of simultaneously projecting a plurality of colored light having sufficient intensity by efficiently utilizing light from a light source. <P>SOLUTION: The light source device is provided with a light source part 2, a light guide rod 5 and a color wheel 6 in which dichroic filters of a plurality of colors are formed on the entire periphery of a rotary board so that these dichroic filters are formed with corresponding width in the width of an area on which outgoing light from the light guide rod 5 is made incident. A polarization conversion element 9 for converting outgoing light from the light source part 2 into straight polarized light having the same polarization surface and making the converted light incident on the light guide rod 5 is arranged between the light source part 2 and the light guide rod 5, a polarized beam splitter 11 for transmitting the straight polarized light transmitted through the polarization conversion element 9 and reflecting straight polarized light orthogonal to the transmitted straight polarized light is arranged on the incident end of the light guide rod 5 and a λ/4 phase difference plate 12 is arranged on the outgoing end of the light guide rod 5. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a light source device and a display device using the same.
[0002]
[Prior art]
It has a plurality of pixels arranged in a matrix in the row and column directions, such as a micromirror display device (Digital Micromirror Device) or a liquid crystal display device, which is generally abbreviated as DMD, and reflects light incident on these pixels. Alternatively, a display device that uses a display body that displays an image by controlling transmission includes a light source device, and light from the light source device is incident on the display body by a light source side optical system to display an image on the display body. It has become.
[0003]
This display device includes a direct-view type in which an emission surface of the display is used as a display surface, and a projection type in which light emitted from the display is projected onto a projection surface such as a screen by a projection optical system and displayed. The micromirror display device is used for a projection display device, and the liquid crystal display device is used for both a direct-view display device and a projection display device.
[0004]
Further, a display device using the micromirror display element or a liquid crystal display element without a color filter as a display body emits a plurality of colors, for example, three colored lights of red, green, and blue from the light source device. By controlling the reflection or transmission of a plurality of pixels of the display according to the color of light incident on each pixel, a color image is displayed on the display.
[0005]
The light source device of the display device has a light source unit that emits light, an incident end and an exit end of the light, and the incident end is arranged to face the light source unit, and guides light incident from the incident end. A light guide rod that emits colored light of a plurality of colors, and a light source device that emits colored light of a plurality of colors faces the emission end of the light guide rod. It is configured to include a coloring unit that emits colored light of a plurality of colors in which the emitted light is colored by a plurality of color filters.
[0006]
As the coloring means, for example, color filters of a plurality of colors (for example, three colors of red, green, and blue) are provided alternately in the circumferential direction on the entire circumference of the rotating plate, and a part of the outer peripheral portion is provided as the guide. A color wheel is used which is arranged so as to face the light emitting end of the optical rod and to fix the center to the rotation axis (see Patent Document 1).
[0007]
The color wheel includes a plurality of color filters that use an absorption filter that transmits light in a transmission wavelength band and absorbs light in other wavelength bands, out of incident light in a visible light band. Some use a dichroic filter that transmits light in a transmission wavelength band and reflects light in another wavelength band.
[0008]
Furthermore, there is a color wheel in which a plurality of color filters of a plurality of colors formed in a fan shape are provided in a circumferential direction (see Patent Document 1). The light source device provided with the color wheel is provided in the color filter. With the rotation of, a plurality of colored lights are sequentially emitted one by one.
[0009]
Further, the color wheel has a width corresponding to a plurality of color filters within a radial width of the rotating plate in a region where the light emitted from the light guide rod is incident, and is provided in a circumferential direction of the rotating plate. There is a color wheel formed in a belt shape curved in an involute curve along the circumference (see Non-Patent Document 1). A light source device provided with the color wheel is capable of emitting colored light of a plurality of colors. Emit simultaneously. The emitted light from the light source device is a stripe-shaped light beam in which colored lights of a plurality of colors are arranged, and the position of the light of each color is arranged in the direction in which the light of each color is arranged with the rotation of the color wheel. Change.
[0010]
Further, in the light source device, between the light source unit and the light guide rod, the light emitted from the light source unit is converted into linearly polarized light having the same polarization plane and is incident on the incident end of the light guide rod. There is also a device in which a polarization conversion element is arranged (see Patent Document 2).
[0011]
[Patent Document 1]
JP 2002-277820 A
[0012]
[Patent Document 2]
JP-A-8-304739
[0013]
[Non-patent document 1]
D. Scott Dewald, Steven M. Penn, and Michael Davis, "Sequential Color Recapture and Dynamic Filtering: A Method of Scrolling Color", TEXT INSTRUMENTS [REAL WORLD CROSS SIGNALS ^TM ], | DLP ^TM Technical Data | Attached file, [Search November 13, 2002] Internet
<URL: http: // www. tij. co. jp / jrd / dip / docs / technology / to_strul. htm>
[0014]
[Problems to be solved by the invention]
However, the light source device provided with the conventional color wheel has a transmission wavelength band of the color filter of the coloring means, out of the light emitted from the light source unit, guided by the light guide rod and incident on the coloring means such as the color wheel. Is transmitted through the color filter and emitted as colored light, and light in the other transmission wavelength band is absorbed (when the color filter is an absorption filter) or reflected (when the color filter is a dichroic filter) by the color filter. ), The efficiency of using light from the light source unit is low.
[0015]
Therefore, in a display device using this light source device, the intensity of the colored light emitted from the light source device is not sufficient, so that a color image with sufficient brightness cannot be displayed on the display.
[0016]
The present invention provides a light source device capable of simultaneously emitting colored light of a plurality of colors of sufficient intensity by efficiently utilizing light from a light source unit, and also providing a color image of sufficient brightness on a display body. It is an object of the present invention to provide a display device capable of displaying.
[0017]
[Means for Solving the Problems]
The light source device of the present invention has a light source unit, an incident end and an emitting end of light, the incident end is arranged to face the light source unit, and the light incident from the incident end is guided from the emitting end. A light guide rod that emits light and a transmissive wavelength band are different from each other, and a dichroic filter of a plurality of colors that transmits light in the transmissive wavelength band and reflects light in other wavelength bands among incident lights in the visible light band is provided. A dichroic filter of a plurality of colors is formed in a width corresponding to each of the dichroic filters within a width of a region where the light emitted from the light guide rod is incident, and the dichroic filters are opposed to the emission end of the light guide rod. The coloring means disposed between the light source unit and the light guide rod is disposed between the light source unit and the light guide rod, and converts the light emitted from the light source unit into linearly polarized light having the same polarization plane at the incident end of the light guide rod. Entering A polarizing beam splitter that is provided at the incident end of the light guide rod, transmits linearly polarized light that has passed through the polarization conversion element, and reflects linearly polarized light that is orthogonal thereto, and an emission end of the light guide rod. And a λ / 4 phase difference plate for providing a phase difference of １ ／ wavelength between the ordinary light and the extraordinary light of the transmitted light.
[0018]
Since this light source device is configured as described above, the light emitted from the light source unit is converted into linearly polarized light having the same polarization plane by the polarization conversion element, and provided at the incident end of the light guide rod. The light passes through the polarization beam splitter and enters the light guide rod.
[0019]
The linearly polarized light incident on the light guide rod is guided inside the light guide rod, is converted into circularly polarized light by a λ / 4 phase difference plate provided at an output end thereof, and is output. Of the dichroic filter, out of the light, the light in the transmission wavelength band of the dichroic filter passes through the dichroic filter to be emitted as colored light, and the light in the other wavelength band is reflected by the dichroic filter. You.
[0020]
The light reflected by the dichroic filters of the plurality of colors has its polarization plane rotated by 90 degrees with respect to the linearly polarized light that has been transmitted through the polarizing beam splitter and incident on the light guide rod by the λ / 4 retardation plate. Linearly polarized light, that is, linearly polarized light of the polarization component reflected by the polarization beam splitter, enters the light guide rod from its emission end, is guided in the light guide rod in the opposite direction, and is reflected by the polarization beam splitter. You.
[0021]
The light reflected by the polarization beam splitter is again guided in the light guide rod in a forward direction through a different path from the light transmitted through the polarization beam splitter from the incident end of the light guide rod and entering the light guide rod. The light is converted into circularly polarized light by the λ / 4 retardation plate and re-enters the coloring means.
[0022]
Therefore, most of the light that has re-entered the coloring means is incident on a dichroic filter of a different color from the dichroic filter that has entered before the dichroic filters of the plurality of colors of the coloring means. The light in the transmission wavelength band of the dichroic filter passes through the dichroic filter and is emitted as colored light.
[0023]
As described above, the light source device of the present invention emits the light from the light source unit, enters the light guide rod from the incident end thereof, guides the inside of the light guide rod, and emits the light from the emission end. The light transmitted through the dichroic filters of the plurality of colors of the coloring means is emitted as colored light of the colors of these dichroic filters, and the light reflected by the dichroic filter and guided in the light guide rod in the opposite direction is emitted. The light reflected by the polarization beam splitter is guided in the light guide rod in a forward direction through a path different from the path of the light incident on the light guide rod from the incident end, and is emitted again from the exit end. Thus, a dichroic filter having a color different from that of the dichroic filter that has entered before the dichroic filter of the plurality of colors of the coloring means. And the light transmitted through the dichroic filter out of the light is emitted as colored light of the color of the dichroic filter. According to this light source device, the light from the light source unit is efficiently emitted. It is possible to simultaneously emit colored lights of a plurality of colors with sufficient intensity by using well.
[0024]
In the light source device of the present invention, the coloring unit includes a plurality of dichroic filters of a plurality of colors arranged alternately in the circumferential direction on the entire circumference of the rotating plate, and these dichroic filters each emit light from the light guide rod. A dichroic filter of a plurality of colors has a corresponding width within the width of the rotating plate in the radial direction of the incident area, and is formed in a band shape curved in an involute curve along the circumferential direction of the rotating plate, and an outer peripheral portion thereof is formed. It is preferable that a part of the light guide rod is opposed to the light-emitting end, and the center of the color wheel is fixed to the rotation axis. By using the color wheel, colored lights of a plurality of colors having sufficient intensity are arranged. A light beam having a stripe-like shape, in which the position of the colored light of each color changes in the arrangement direction of the colored light of each color with the rotation of the color wheel. Rukoto can.
[0025]
The coloring means may be a striped color panel in which a plurality of linear strip-shaped dichroic filters are alternately arranged in parallel in the width direction and provided in parallel, and are arranged opposite to the emission end of the light guide rod. By using the striped color panel, a striped luminous flux in which colored lights of a plurality of colors having sufficient intensity are arranged can be emitted.
[0026]
The display device of the present invention has a light source unit that emits light, an incident end of light, and an exit end of the light, and is disposed with the incident end facing the light source unit, and guides light incident from the incident end. The light guide rods emitted from the emission end and the entire circumference of the rotating plate have different transmission wavelength bands, and among the incident light in the visible light band, the light in the transmission wavelength band is transmitted, and the light in the other wavelength band is transmitted. Dichroic filters of a plurality of colors that reflect light are provided alternately in the circumferential direction, and each of these dichroic filters has a plurality of dichroic filters within a width in a rotating plate radial direction of a region where light emitted from the light guide rod is incident. The color dichroic filter has a corresponding width, is formed in a band shape curved in an involute curve along the circumferential direction of the rotating plate, and a part of the outer peripheral portion thereof is opposed to the emission end of the light guide rod, During ~ A color wheel fixedly disposed on a rotation axis, and disposed between the light source unit and the light guide rod, and converts the light emitted from the light source unit into linearly polarized light having the same polarization plane. A polarization conversion element that is incident on the incident end of the light guide rod, and a polarization beam splitter that is provided at the incident end of the light guide rod, transmits linearly polarized light that has passed through the polarization conversion element, and reflects linearly polarized light that is orthogonal thereto. A light source device comprising: a λ / 4 phase difference plate provided at an emission end of the light guide rod and providing a phase difference of １ ／ wavelength between ordinary light and extraordinary light of transmitted light;
It has a plurality of pixels arranged in a matrix in the row direction and the column direction, and the row direction is orthogonal to the rotating plate radial direction of a region where the light emitted from the light guide rod of the color wheel of the light source device is incident. A display that is arranged and controls the reflection or transmission of light incident on the plurality of pixels to display an image,
An optical system for causing the plurality of colors of light emitted from the light source device to pass through the dichroic filters of the plurality of colors of the color wheel and to enter the display body;
Monochromatic image data of a plurality of colors corresponding to the colors of the respective dichroic filters of the color wheel are sequentially incident on the pixels of the respective rows of the display body with the rotation of the color wheel. Display driving means for sequentially writing in synchronization with the incident timing of the plurality of colored lights.
[0027]
This display device causes the plurality of colored lights emitted from the light source device through the dichroic filters of the plurality of colors of the color wheel to be incident on the display, and the pixels of each row of the display are respectively Monochromatic image data of a plurality of colors corresponding to the colors of the dichroic filters of the color wheel are input to the pixels of each row of the display body sequentially with the rotation of the color wheel at the incident timing of the colored lights of the plurality of colors. By writing sequentially in synchronization with each other, a single color image of a plurality of colors is sequentially displayed on each pixel row of the display body, and a color image obtained by combining the single color images of these colors is observed.
[0028]
According to this display device, as described above, the light source device is a striped luminous flux in which a plurality of colored lights of sufficient intensity are arranged, and the position of the colored light of each color is determined by the rotation of the color wheel. In order to emit light that changes in the direction in which the colored lights of the respective colors are arranged, a single-color image of a plurality of colors is sequentially displayed on each pixel row of the display with sufficient brightness, and a high-luminance color image is displayed. Obtainable.
[0029]
Further, another display device of the present invention has a light source unit that emits light, an incident end and an exit end of light, the incident end is arranged to face the light source unit, and light enters from the incident end. A light guide rod that guides light and emits light from the emission end, and a plurality of linear dichroic filters of a linear band are alternately arranged in the width direction and provided in parallel with each other, and these dichroic filters are respectively separated from the light guide rod. A plurality of dichroic filters of a plurality of colors formed in a corresponding width within a width of a region on which the outgoing light is incident, and a stripe-shaped color panel arranged and fixed to face an emission end of the light guide rod; and the light source unit. A polarization conversion element disposed between the light guide unit and the light guide rod, the light conversion unit converting the light emitted from the light source unit into linearly polarized light having the same polarization plane, and entering the light into the incident end of the light guide rod. A polarizing beam splitter that is provided at an incident end of the light guide rod, transmits linear polarized light that has passed through the polarization conversion element, and reflects linear polarized light that is orthogonal to the polarized light; A light source device including a λ / 4 phase difference plate that gives a phase difference of １ ／ wavelength between ordinary light and extraordinary light;
A plurality of pixels arranged in a matrix in a row direction and a column direction, wherein the row direction is arranged in parallel with a length direction of a dichroic filter of a plurality of colors of a striped color panel of the light source device; A display body for displaying an image by controlling the reflection or transmission of light incident on the pixels of
One frame is divided into a plurality of single-color image data of a plurality of colors corresponding to the colors of the dichroic filters of the striped color panel, respectively, for each of the pixels of a plurality of pixel rows including a predetermined number of pixel rows of the display. Display driving means for sequentially and monochromatic image data for each pixel row group in the same field and written alternately for each field;
The direction of the luminous flux of the colored light of a plurality of colors emitted from the light source device through the dichroic filters of the plurality of colors of the striped color panel is changed in the direction in which the pixel rows of the display body are arranged, and the plurality of the luminous fluxes are changed. And an optical system for causing the colored light of each color to be incident on a pixel row group in which monochromatic image data corresponding to the color of the light among a plurality of pixel row groups of the display body is written. I do.
[0030]
The display device includes a plurality of single-color image data of a plurality of colors corresponding to the colors of the respective dichroic filters of the stripe-shaped color panel, each of which is divided into a plurality of fields by a plurality of pixels of a plurality of pixel row groups of the display body. In addition to writing the monochromatic image data for each pixel row group in the same field alternately and sequentially, and transmitting and emitting the plurality of colors of dichroic filters of the striped color panel from the light source device. The direction of the luminous flux of the colored light of the color is changed in the direction in which the pixel rows of the display body are arranged, and the colored lights of the plurality of colors of the luminous flux are respectively emitted from the plurality of pixel row groups of the display body. The display color of the plurality of pixel row groups for each field is alternately displayed on the display by irradiating the pixel row group where the monochrome image data corresponding to the color is written. To display the different single-color images, these single-color images to observe the color image combined.
[0031]
According to this display device, as described above, since the light source device emits a stripe-shaped light beam in which a plurality of colored lights of sufficient intensity are arranged, a plurality of pixel row groups of the display body are formed. The monochrome images of the plurality of colors are sequentially displayed with sufficient brightness, and a high-luminance color image can be obtained.
[0032]
In this display device, the optical system that causes the light beam emitted from the light source device to enter the display body has a polygonal cylindrical shape in which flat surfaces of an integral multiple of the number of colors of the light beam are continuous in the circumferential direction. Each flat surface corresponding to the number of colors of light has an angle with respect to a radial line passing through the center of the polygonal tube and the center of the flat surface in the circumferential direction of the polygonal tube according to the pitch of the pixel row group of the display. A configuration in which a rotating mirror is formed on a reflecting surface having a different ratio, and one of the reflecting surfaces is rotated in such a manner that one of the reflecting surfaces faces the incident direction of the light flux for each field, with the center of the polygonal tube as a rotation center. Is preferred.
[0033]
Further, in this display device, for example, monochromatic image data to be written into pixels of a plurality of pixel rows of the display by the display driving means is converted into three-color image data, and the three-color dichroic filter is provided to the light source device. When the light source device is provided with a plurality of striped color panels alternately arranged, the total number of the three colored lights transmitted through the three dichroic filters is greater than the number of the pixel row groups of the display. It is preferable to emit at least two or more stripe-shaped light beams.
[0034]
It is preferable that each of the display devices according to the present invention further includes a projection optical system that projects light emitted from the display body onto a projection surface.
[0035]
BEST MODE FOR CARRYING OUT THE INVENTION
1 to 7 show a first embodiment of the present invention. FIG. 1 is a configuration diagram of a display device, FIG. 2 is an enlarged side view of a light guide rod and coloring means of the light source device, and FIG. It is a perspective view of a coloring means.
[0036]
First, the configuration of the display device shown in FIG. 1 will be described. This display device has a light source device 1 and a plurality of pixels arranged in a matrix in a row direction and a column direction. A display 13 for displaying an image by controlling the reflection or transmission of light, a light source side optical system 14 for causing light emitted from the light source device 1 to enter the display 13, and light emitted from the display 13. A projection optical system 16 for projecting onto a projection surface such as a screen or the like, and an output light from the light source side optical system 14 is corrected into a parallel light to be incident on the display 13 and the output light from the display 13 is It comprises a relay lens 18 for entering the projection optical system 16 and a display driving means 19 for driving the display 13.
[0037]
Note that the light source side optical system 14 is configured by a light source side lens 15 designed so that light emitted from the light source device 1 is focused and incident on the display body 13, and the projection optical system 16 is It is constituted by a projection lens 17 designed to project light emitted from the display body 13 in focus on the projection plane.
[0038]
This display device uses a micromirror display element as the display body 13. Although not shown, the micromirror display element 13 has one of the mirror driving elements based on CMOS. A plurality of pixels composed of micromirrors (extremely thin metal pieces having a vertical and horizontal width of 10 μm to 20 μm) tilted in the tilt direction and the other tilt direction are arranged in a matrix in the row direction and the column direction. .
[0039]
The micromirror display element 13 emits light incident at a predetermined incident angle from an incident direction inclined in one inclination direction of the micromirror with respect to the front direction by switching the inclination directions of the plurality of micromirrors. An image is displayed by reflecting in the front direction and the oblique direction.
[0040]
The projection optical system 16 is arranged so that reflected light emitted in the front direction of the micromirror display element 13 is taken into the projection lens 17 and projected on a projection surface.
[0041]
Next, the configuration of the light source device 1 will be described. As shown in FIGS. 1 and 2, the light source device 1 includes a light source unit 2 that emits light and a light guide that is disposed on the emission side of the light source unit. An optical rod 5 and coloring means 6 disposed on the emission side of the light guide rod 5, and the light emitted from the light source 2 is provided between the light source 2 and the light guide rod 5. A polarization conversion element 9 for converting into linearly polarized light having a polarization plane in one direction, and a condensing lens 10 for condensing light emitted from the light source unit 2 and making the light incident on the light guide rod 5. Is disposed at an incident end of the light guide rod 5 facing the light source unit 2, and a polarization beam splitter 11 that transmits linearly polarized light transmitted through the polarization conversion element 9 and reflects linearly polarized light orthogonal thereto is provided. At the same time, the ordinary end of the transmitted light is Provides a phase difference of a quarter wavelength lambda / 4 phase plate 12 has a configuration which is provided between the extraordinary light.
[0042]
The light source unit 2 includes a light source lamp 3 that emits high-luminance white light, and a reflector 4 that reflects light emitted from the light source lamp 3 and emits the light forward.
[0043]
The polarization conversion element 9 converts light emitted from the light source unit 2 into linearly polarized light having the same polarization plane and causes the light to enter the incident end of the light guide rod 5. One of the two linearly polarized light components is transmitted and emitted, and the other polarized light component is emitted by rotating its polarization plane by substantially 90 degrees.
[0044]
As a polarization conversion element having such characteristics, for example, as described in Patent Document 2, a polarization separation prism array in which a plurality of polarization beam splitters are arranged in parallel with each other is provided. Of the two orthogonal linearly polarized light components that have entered, one of the polarized light components is transmitted through the polarizing beam splitter and emitted to the other surface, and the other polarized light component is reflected by the polarizing beam splitter and adjacent polarized light components are reflected. The light enters the beam splitter, is further reflected by the polarization beam splitter, and is emitted to the other surface side. The polarization plane of the emitted light of one of the one and the other polarization components is set to 90 ° by a λ / 2 phase plate. In some cases, both polarization components are emitted as linearly polarized light having the same polarization plane.
[0045]
The light guide rod 5 is a rectangular rod-shaped transparent body made of glass or the like, one end of which is an incident end, and the other end of which is an emission end.
[0046]
The light guide rod 5 guides the light incident from the incident end thereof while totally reflecting the light at the interface between the rod outer peripheral surface and the air layer, which is the outside air, and emits the light from the output end. Light is emitted as light having a uniform intensity distribution.
[0047]
The end face on the incident side of the light guide rod 5 is formed as an inclined face inclined at an angle of substantially 45 degrees with respect to the rod axis, and the inclined end face is formed of a right-angled triangular horizontally long prism. The polarization splitting surface 11a of the polarization beam splitter 11 having the inclined surface formed as the polarization splitting surface 11a is attached.
[0048]
The end face of the light guide rod 5 on the emission side is formed in a plane perpendicular to the rod axis, and the λ / 4 retardation plate 12 is attached to the end face.
[0049]
In this embodiment, the light guide rod 5 is a square rod-shaped transparent body, but the light guide rod 5 is formed by bonding four plate members such as glass plates together at their side edges, It may be a rectangular cylinder in which a reflective film is provided on the entire inner peripheral surface.
[0050]
On the other hand, as shown in FIG. 3, the coloring means 6 arranged on the emission side of the light guide rod 5 has different transmission wavelength bands over the entire circumference of the circular rotary plate, and the incident light of the visible light band is different. Among these, a dichroic filter of a plurality of colors that transmits light in the transmission wavelength band and reflects light in other wavelength bands, for example, a red color that transmits light in the red wavelength band and reflects light in the other wavelength band A dichroic filter 7R, a green dichroic filter 7G that transmits light in a green wavelength band and reflects light in another wavelength band, and a blue color that transmits light in a blue wavelength band and reflects light in another wavelength band. The dichroic filters 7B and 7B are color wheels provided alternately in the circumferential direction. The dichroic filters 7R, 7G, and 7B of the respective colors of the color wheel 6 are respectively provided from the light guide rod 5. A plurality of dichroic filters of a plurality of colors have corresponding widths within the width of the rotating plate radial direction in the region where the emitted light is incident, and are formed in a band shape curved in an involute curve along the circumferential direction of the rotating plate. .
[0051]
In this embodiment, the red, green, and blue dichroic filters 7R, 7G, and 7B correspond one by one within the width of the rotating plate radial direction in the area where the light emitted from the light guide rod 5 is incident. The dichroic filters 7R, 7G, and 7B of the respective colors are each formed to have a width approximately 1/3 of the area.
[0052]
As shown in FIGS. 1 and 2, the color wheel 6 has a part of an outer peripheral portion thereof opposed to an emission end of the light guide rod 5, and has a center located at a side of the emission end of the light guide rod 5. The motor 8 is fixedly arranged on the rotating shaft 8a of the motor 8 and is driven to rotate at high speed by the motor 8.
[0053]
In the light source device 1, light emitted from the light source unit 2 is guided by the light guide rod 5 to be incident on the color wheel 6, and the light is transmitted to the red, green and blue dichroic filters 7R and 7G of the color wheel 6. , 7B, and emits red, green, and blue, respectively. The dichroic filters 7R, 7G, 7B of the respective colors of the color wheel 6 emit light from the light guide rod 5 as described above. The red, green, and blue dichroic filters 7R, 7G, and 7B each have a corresponding width within the radial width of the rotating plate in the region where the light enters, and form an involute curve along the circumferential direction of the rotating plate. The light emitted from the light source device 1 is a striped light beam S in which red, green, and blue colored lights R, G, and B are arranged, and the light beam emitted from the light source device 1 is formed in a curved band shape. each Light R, G, position B of changes said each color light R with the rotation of the color wheel 6, G, the aligning direction of B.
[0054]
In the light source device 1, red, green, and blue dichroic filters 7R, 7G, and 7B are alternately provided on the emission side of the light guide rod 5, and the dichroic filters 7R, 7G, and 7B are respectively provided with the dichroic filters 7R, 7G, and 7B. A color wheel 6 in which dichroic filters of a plurality of colors are formed in a corresponding width within a width of a region where the light emitted from the light rod 5 is incident is disposed between the light source 2 and the light guide rod 5. A polarization conversion element 9 that converts light emitted from the light source unit 2 into linearly polarized light having the same polarization plane and causes the light to enter the incident end of the light guide rod 5 is disposed. A polarization beam splitter 11 that transmits linearly polarized light that has passed through the polarization conversion element 9 and reflects linearly polarized light that is orthogonal thereto is provided. Since there is provided a retardation plate 12, and efficiently utilize the light from the light source unit 2, red sufficient strength, green can be emitted colored light R and blue, G, and B at the same time.
[0055]
That is, in the light source device 1, the light emitted from the light source unit 2 is converted into linearly polarized light having the same polarization plane by the polarization conversion element 9, and the polarized light provided at the incident end of the light guide rod 5. The light passes through the beam splitter 11 and enters the light guide rod.
[0056]
The linearly polarized light that has entered the light guide rod 5 is guided inside the light guide rod 5, is converted into circularly polarized light by a λ / 4 retardation plate 12 provided at an output end thereof, and is output. Incident on the incident area facing the light guide rod 5.
[0057]
The light incident on the incident area of the color wheel 6 is incident on the dichroic filters 7R, 7G, 7B of red, green, and blue in the incident area, and among the light, the dichroic filters 7R, 7G are included. , 7B pass through the dichroic filters 7R, 7G, 7B and become red, green, and blue colored lights R, G, and B, and are emitted. As shown in FIG. 2, the light is reflected by the dichroic filters 7R, 7G, 7B.
[0058]
The light reflected by the dichroic filters 7R, 7G, 7B of the respective colors is polarized by the λ / 4 phase difference plate 12 with respect to the linearly polarized light that has passed through the polarization beam splitter 11 and entered the light guide rod 5. It becomes linearly polarized light whose plane is rotated by 90 degrees, that is, linearly polarized light of the polarized light component reflected by the polarization beam splitter 11, enters the light guide rod 5 from its emission end, and guides the inside of the light guide rod 5 in the opposite direction. Then, the light is reflected by the polarization beam splitter 11.
[0059]
The light reflected by the polarization beam splitter 11 travels in the light guide rod 5 again in the forward direction through a different path from the light transmitted through the polarization beam splitter 11 from the incident end of the light guide rod 5 and entered. The light is guided into a circularly polarized light by the λ / 4 retardation plate 12 and re-enters the incident area of the color wheel 6.
[0060]
Therefore, most of the light that has re-entered the incident area of the color wheel 6 enters the dichroic filters 7R, 7G, and 7B, which are different in color from the dichroic filter that has previously entered, and among the light, the dichroic filter Light in the transmission wavelength band of 7R, 7G, 7B passes through the dichroic filters 7R, 7G, 7B and is emitted as colored light.
[0061]
The path of the light reflected by the dichroic filter shown in FIG. 2 is the path of the light RB in the red and blue wavelength bands reflected by the green dichroic filter 7G of the color wheel 6, and this light RB is the polarization beam splitter. Most of the light reflected by 11 is incident on the red dichroic filter 7R and the blue dichroic filter 7B of the color wheel 6, and the light in the blue wavelength band of the light incident on the blue dichroic filter 7B is as shown in the figure. The red light passes through the blue dichroic filter 7B and is emitted as blue colored light B, and the light in the red wavelength band of the light incident on the red dichroic filter 7R passes through the red dichroic filter 7R. And emits as red colored light R.
[0062]
The same applies to the light reflected by the red dichroic filter 7R and the blue dichroic filter 7B of the color wheel 6, for example, the light reflected by the red dichroic filter 7R and reflected by the polarization beam splitter 11 (green and blue). Most of the light in the wavelength band of the green light enters the green dichroic filter 7G and the blue dichroic filter 7B of the color wheel 6, and the light in the green wavelength band of the light that has entered the green dichroic filter 7G is: The light passes through the green dichroic filter 7G to be emitted as green colored light G, and the light in the blue wavelength band of the light incident on the blue dichroic filter 7B passes through the blue dichroic filter 7B. Emitted as blue colored light B
[0063]
As described above, the light source device 1 emits light from the light source unit 2, enters the light guide rod 5 from the incident end thereof, guides the inside of the light guide rod 5 and emits light from the emission end. The light transmitted through the red, green, and blue dichroic filters 7R, 7G, and 7B in the incident area of the color wheel 6 is colored by the dichroic filters 7R, 7G, and 7B. And the light reflected by the dichroic filters 7R, 7G, 7B and guided in the light guide rod 5 in the opposite direction is reflected by the polarization beam splitter 11, and the light is reflected by the light guide rod 5. The light is guided in the forward direction through the light guide rod 5 through a path different from the path of the light incident from the light incident end thereof, and is emitted again from the light emitting end. The dichroic filters 7R, 7G, and 7B having different colors from the dichroic filters that have entered the front of the dichroic filters 6A and 6B. , 7B as colored light R, G, B.
[0064]
Therefore, according to the light source device 1, the light from the light source unit 2 is efficiently used, and the red, green, and blue colored lights R, G, and B having sufficient intensity are arranged in a striped light flux S, The light of which the position of the light R, G, B of each color changes in the arrangement direction of the light R, G, B of the respective color with the rotation of the color wheel 6 can be emitted.
[0065]
Next, the display operation of the display device shown in FIG. 1 will be described. Light emitted from the light source device 1 and incident on the micromirror display element 13 through the light source side optical system 14 is red, It is a striped light flux S in which green, blue lights R, G, and B are arranged. The position of the colored light R, G, and B of each color of the light flux S is caused by the rotation of the color wheel 6 of the light source device 1. It changes in the arrangement direction of the colored light R, G, B of each color.
[0066]
On the other hand, the micromirror display element 13 is arranged such that its row direction, that is, the direction along each pixel row, corresponds to the rotation plate radial direction of the area where the light emitted from the light guide rod 5 of the color wheel 6 of the light source device 1 is incident. And a timing corresponding to the rotation speed of the color wheel 6, that is, the changing speed of the stripe light flux S in the direction in which the colored lights R, G, and B are arranged in the arrangement direction. Is driven for display.
[0067]
The display driving means 19 applies a plurality of colors corresponding to the colors of the dichroic filters 7R, 7G, 7B of the color wheel 6, that is, three colors of red, green, and blue to the pixels of each row of the micromirror display element 13, respectively. The monochrome monochromatic image data is sequentially synchronized with the incident timing of the red, green, and blue lights R, G, and B sequentially incident on each pixel row of the micromirror display element 13 as the color wheel 6 rotates. Write.
[0068]
4 to 7 show the relationship between the change of the stripe light beam S incident on the micromirror display element 13 and the monochromatic image data written in each pixel row of the micromirror display element 13 by the display driving means 19. In the figure, a region 13a surrounded by a thick line indicates a display area in which a plurality of pixels of the micromirror display element 13 are arranged in a matrix.
[0069]
The striped light flux S is always incident on the entire display area 13a of the micromirror display element 13, and the positions of the red, green, and blue lights R, G, and B are determined by the color wheel 6 of the light source device 1. With the rotation, the arrangement direction of the colored lights R, G, and B of each color, that is, the arrangement direction of each pixel row a of the micromirror display element 13 changes as shown in FIGS.
[0070]
On the other hand, the display driving means 19 performs writing for sequentially selecting each pixel row of the micromirror display element 13 for each row and switching the tilt direction of the micromirror of each pixel of each pixel row. As shown in FIGS. 4 to 7, the micromirror display element 13 is synchronized with the incident timing of red, green, and blue lights R, G, and B sequentially incident on each pixel row a of the micromirror display element 13. Red monochromatic image data D is applied to each pixel of all the pixel rows a in the area where the red light R is incident. _R Is written to each pixel of all the pixel rows a in the area where the green light G is incident. _G Is written to each pixel of all the pixel rows a in the region where the blue light B is incident. _B Write.
[0071]
Then, the micromirror display element 13 changes the tilt direction of the micromirror of each pixel in the area where the red light R is incident on the red monochrome image data D. _R And the inclination direction of the micromirror of each pixel in the area where the green light G is incident is changed to the green single-color image data D. _G And the inclination direction of the micromirror of each pixel in the region where the blue light B is incident is changed to the blue monochromatic image data D. _B , And a single color image of red, green, and blue is sequentially displayed by each pixel row a.
[0072]
The light emitted from the micromirror display element 13, that is, the red, green, and blue lights R, G, and B reflected in the front direction by the micromirrors of each pixel row a have their light fluxes expanded by the projection optical system 16. Are projected onto the projection surface, and are viewed as a combined color image of red, green, and blue monochromatic images displayed by each pixel row of the micromirror display element 13.
[0073]
That is, the image projected on the projection surface is such that the color of the single-color image, which is the display of each pixel row a of the micromirror display element 13, is red at a speed corresponding to the rotation speed of the color wheel 6 of the light source device 1. The image changes in the order of → green → blue, so that a color image in which a single-color image of these colors is synthesized can be observed.
[0074]
As described above, the display device includes red, green, and blue colored lights R, G, and blue emitted from the light source device 1 through the red, green, and blue dichroic filters 7R, 7G, and 7B of the color wheel 6. B is made incident on the micromirror display element 13, and a single color of red, green, and blue corresponding to the color of each of the dichroic filters 7 R, 7 G, and 7 B of the color wheel 6 is applied to the pixels of each row of the micromirror display element 13. Image data D _R , D _G , D _B Are sequentially written in synchronization with the incident timing of the red, green, and blue lights R, G, and B sequentially incident on the pixels of each row of the micromirror display element 13 with the rotation of the color wheel 6. A single color image of red, green, and blue is sequentially displayed on each pixel row of the micromirror display element 13, and a color image obtained by combining the single color images of these colors is observed.
[0075]
In this display device, as described above, the light source device 1 is a striped luminous flux S in which red, green, and blue light R, G, and B of sufficient intensity are arranged, and the colored light of each color is provided. Since the positions of R, G, and B emit light that changes in the arrangement direction of the colored lights R, G, and B of the respective colors with the rotation of the color wheel 6, each pixel row a of the micromirror display element 13 is emitted. , A red, green, and blue monochromatic image is sequentially displayed with sufficient brightness, and a high-luminance color image can be obtained.
[0076]
In addition, since this display device further includes a projection optical system 16 that projects the light emitted from the micromirror display element 13 onto a projection surface, the display image of the micromirror display element 13 is enlarged and projected onto the projection surface. Can be displayed.
[0077]
8 and 7 show a second embodiment of the present invention. FIG. 1 is a configuration diagram of a display device, and FIG. 2 is an enlarged side view of a coloring means of the light source device.
[0078]
The display device of this embodiment includes a light source device 1a having a stripe-shaped color panel 6a as coloring means, a display body including the micromirror display element 13 described above, and a light output from the light source device 1a. A light source side optical system 20 for entering the element 13; a projection optical system 24 for projecting light emitted from the micromirror display element 13 onto a projection surface such as a screen (not shown); and a display drive for driving the micromirror display element 13 Means 26.
[0079]
First, the light source device 1a will be described. As shown in FIG. 8, the light source device 1a includes a light source unit 2 that emits light, a light guide rod 5 disposed on an emission side of the light source unit, and The stripe-shaped color panel 6a arranged on the emission side of the light guide rod 5, the polarization conversion element 9 and the condenser lens 10 arranged between the light source unit 2 and the light guide rod 5, the light guide It comprises a polarization beam splitter 11 provided at the input end of the rod 5 and a λ / 4 phase difference plate 12 provided at the output end of the light guide rod 5.
[0080]
The light source unit 2 and the light guide rod 5 are substantially the same as those of the first embodiment described above, and a polarization conversion element 9, a condenser lens 10, a polarization beam splitter 11, and a λ / 4 Since the phase difference plate 12 is also the same as that of the first embodiment, the duplicate description will be omitted.
[0081]
FIG. 9 is an enlarged side view of the striped color panel 6a. The striped color panel 6a has a plurality of dichroic filters 7Ra, 7Ga, and 7Ba of three colors, such as red, green, and blue, alternately arranged in a linear band. And the dichroic filters 7Ra, 7Ga, and 7Ba are arranged within the width of a region where the light emitted from the light guide rod 5 is incident, respectively, and the red, green, and blue dichroic filters 7Ra, 7Ga, 7Ba is formed to have a corresponding width, and the striped color panel 6a is arranged and fixed to face the emission end of the light guide rod 5.
[0082]
In this embodiment, the stripe-shaped color panel 6a is formed so as to have an entire area on which the light emitted from the light guide rod 5 is incident, and the dichroic filters 7Ra, 7Ga, and 7Ba are respectively provided with the light guides. All of the red, green, and blue dichroic filters 7Ra, 7Ga, and 7Ba are formed to have corresponding widths within the width of the region where the light emitted from the rod 5 is incident.
[0083]
The total number of red, green, and blue dichroic filters 7Ra, 7Ga, and 7Ba of the striped color panel 6a is set to be at least two more than the number of pixel row groups of the micromirror display element 13 described later. Have been.
[0084]
The light source device 1a emits light emitted from the light source unit 2, guided by the light guide rod 5, and emitted from an emission end thereof by being colored by the stripe color panel 6a and emitted. A red, green, and blue colored light R, G, and B transmitted through the dichroic filters 7Ra, 7Ga, and 7Ba of the three colors red, green, and blue of the color panel 6a emit a stripe-shaped light flux Sa that is alternately arranged. .
[0085]
The light emitted from the light source device 1 of the first embodiment described above is a striped light flux S in which red, green, and blue lights R, G, and B change in the direction in which they are arranged as the color wheel 6 rotates. However, the emitted light from the light source device 1a in this embodiment is a striped luminous flux in which the positions of the red, green, and blue lights R, G, and B do not change because the striped color panel 6a is fixed. S.
[0086]
In the light source device 1a, red, green, and blue dichroic filters 7Ra, 7Ga, and 7Ba are provided alternately on the emission side of the light guide rod 5, and the dichroic filters 7Ra, 7Ga, and 7Ba are respectively provided with the dichroic filters 7Ra, 7Ga, and 7Ba. A striped color panel 6a in which the dichroic filters 7Ra, 7Ga, and 7Ba of the plurality of colors are formed in a corresponding width is arranged within a width of a region where the light emitted from the optical rod 5 is incident. A polarization conversion element 9 for converting light emitted from the light source unit 2 into linearly polarized light having the same polarization plane and incident on the incident end of the light guide rod 5 is disposed between the light guide unit 5 and the light rod 5. A polarization beam splitter 11 that transmits linearly polarized light transmitted through the polarization conversion element 9 and reflects linearly polarized light orthogonal to the linearly polarized light at the incident end of the optical rod 5. Since the λ / 4 phase difference plate 12 is provided at the emission end of the light guide rod 5, the light from the light source unit 2 is efficiently used, and the red, green, and blue light R of sufficient intensity is used. , G, and B can be emitted.
[0087]
Next, another configuration of the display device of this embodiment will be described. The display driving means 26 sequentially selects each pixel row of the micromirror display element 13 for each row, and selects each pixel of the pixel row. The writing is performed to switch the tilt direction of the micromirror, and the pixels of the plurality of pixel rows of the micromirror display element 13 corresponding to the color of the light emitted from the light source device 1a. A plurality of single-color image data, that is, single-color image data of red, green, and blue are sequentially divided for each field by dividing one frame into a plurality of (three) color numbers of red, green, and blue, and each pixel in the same field. The monochromatic image data for each row group is alternately written.
[0088]
The micromirror display element 13 is, for example, a display element having 768 pixel rows and 1024 pixel columns. In this embodiment, the display driving means 26 is used to control the total number of pixels of the micromirror display element 13. The row (768 rows) is divided into 32 pixel row groups each composed of 24 pixel rows, and the red, green, and blue single-color image data are respectively applied to the pixels of these pixel row groups for each of the fields. The configuration is such that monochromatic image data for each pixel row group in the same field is sequentially and alternately written.
[0089]
Further, the light source side optical system 20 is provided with the red, green and blue dichroic filters 7Ra. The direction of the stripe light flux Sa of the red, green, and blue lights R, G, and B transmitted and emitted through 7Ga and 7Ba is changed in the direction in which the pixel rows of the micromirror display element 13 are arranged, and the red light of the light flux Sa is changed. , Green, and blue light R, G, and B, respectively, are incident on a pixel row group to which monochromatic image data corresponding to the color of the light is written out of the plurality of pixel row groups of the micromirror display element 13. Is configured.
[0090]
The light source side optical system 20 includes a correction lens 21 that corrects the red, green, and blue light R, G, and B stripe light flux Sa emitted from the light source device 1a into parallel light, and a parallel light that is corrected by the correction lens 21. And the reflection means 22 for reflecting the stripe light flux Sa corrected toward the micromirror display element 13 and changing the reflection direction of the light flux Sa in the direction in which the pixel rows of the micromirror display element 13 are arranged. Has become.
[0091]
As shown in FIG. 8, the reflection means 22 is an integer multiple of the number of colors (three colors of red, green, and blue) of the stripe light flux Sa which has been corrected into parallel light by the correction lens 21 and entered. A flat surface of the same width is a polygonal cylindrical shape that is continuous in the circumferential direction, for example, the red, green, hexagonal cylindrical shape that has six flat surfaces of the same width that is twice the number of colors of blue, Each flat surface corresponding to the number of colors, that is, every other flat surface, defines an angle θa, θb, θc with respect to a radial line r passing through the center of the polygonal tube and the center of the flat surface in the circumferential direction of the polygonal tube. The micromirror display element 13 is composed of rotating mirrors formed on reflecting surfaces 23a, 23b, and 23c that are different at a ratio corresponding to the pitch of a plurality of pixel rows (hereinafter, the reflecting means 22 is referred to as a rotating mirror). To tell).
[0092]
The rotating mirror 22 is disposed with its peripheral surface facing the direction of incidence of the striped light beam Sa. The micromirror is driven by the display driving means 26 by a motor (not shown) using the center of the polygonal tube as the rotation center O. In synchronization with the writing of monochromatic image data to each pixel row group of the display element 13, the reflection surfaces 23a, 23b, and 23c are sequentially rotated for each field described above so as to face the incident direction of the stripe light flux Sa. You.
[0093]
Further, the micromirror display element 13 changes the incident direction inclined in one inclination direction with respect to the front direction (the emission direction of the reflected light projected on the projection surface by the projection optical system 24) by the rotating mirror 22. When any one of the reflection surfaces 23a, 23b, and 23c is rotated so as to face the incident direction of the stripe-shaped light beam Sa, the light is directed to the reflection direction of the light beam Sa by the rotating mirror 22, and the micromirror display element is provided. 13 are arranged so that the row direction (the direction along each pixel row) is parallel to the length direction of the dichroic filters 7Ra, 7Ga, 7Ba of the striped color panel 6a of the light source device 1a.
[0094]
The projection optical system 24 includes a projection lens 25 designed to project the light emitted from the micromirror display element 13 (light emitted in the front direction) on the projection surface in focus. The projection optical system 24 is arranged so that reflected light emitted in the front direction of the micromirror display element 13 is taken into the projection lens 25 and projected on a projection surface.
[0095]
Explaining the display operation of this display device, the display drive means 26 divides the single-color image data of red, green, and blue into a plurality of frames for each pixel of a plurality of pixel rows of the micromirror display element 13. Then, the monochrome image data for each pixel row group in the same field is written alternately and sequentially in each field.
[0096]
On the other hand, the light emitted from the light source device 1 is a stripe light flux Sa in which red, green, and blue lights R, G, and B are alternately arranged, as described above. The plurality of pixel rows of the micromirror display element 13 are sequentially changed by the light source side optical system 20 including the rotating mirror 22 in the arrangement direction of the pixel row group of the micromirror display element 13 for each field. It is incident on a pixel row group in which monochromatic image data corresponding to the light color of the group is written.
[0097]
In this embodiment, the stripe color panel 6a of the light source device 1a is connected to the red, green, and blue dichroic filters 7Ra, 7Ga, and 7Ba within the width of the area where the light emitted from the light guide rod 5 is incident. In addition, all the dichroic filters 7Ra, 7Ga, 7Ba are formed to have corresponding widths, and the total number of the dichroic filters 7Ra, 7Ga, 7Ba is increased to four more than the number of pixel rows of the micromirror display element 13. In this configuration, the light source device 1a emits a stripe light beam Sa in which the total number of red, green, and blue lights R, G, and B is four more than the number of pixel rows of the micromirror display element 13. I have to.
[0098]
Therefore, the total number of red, green, and blue lights R, G, and B of the stripe light beam Sa incident on the micromirror display element 13 is four more than the number of pixel rows of the micromirror display element 13. Therefore, the red, green, and blue lights R, G, and B can be made incident on all the pixel row groups of the micromirror display element 13.
[0099]
10 to 12 show the relationship between the writing of monochromatic image data of red, green, and blue to the micromirror display element 13 for each field and the incidence of the stripe light flux Sa on the micromirror display element 13. In the figure, an area 13a surrounded by a thick line indicates a display area of the micromirror display element 13.
[0100]
The writing of monochromatic image data and the incidence of the stripe-shaped light beam Sa on the micromirror display element 13 will be described. Of the fields obtained by dividing one frame into three, the first field includes the micromirror as shown in FIG. The first, fourth, seventh,..., 28th and 31st pixel row groups A among 32 pixel row groups of the display element 13 each including 24 pixel rows. ₁ , A ₄ , A ₇ ... A ₂₈ , A ₃₁ To red monochromatic image data D _R Are written, and the second, fifth, eighth,..., 29th and 32nd pixel row groups A ₂ , A ₅ , A ₈ ... A ₂₉ , A ₃₂ To the green single-color image data D _G Are written, and the third, sixth, ninth,..., Thirtieth pixel row groups A ₃ , A ₆ , A ₉ ... A ₃₀ To each of the blue monochromatic image data D _B Is written, and the striped light beam Sa emitted from the light source device 1a is reflected by the first reflection surface 23a of the rotating mirror 22, and the four lower lights R, G, and B of the light beam Sa are converted to light. The red light R is incident on the outside of the display area 13a of the micromirror display element 13 and out of the other 32 lights R, G, B, the red monochromatic image data D _R Pixel group A in which is written ₁ , A ₄ , A ₇ ... A ₂₈ , A ₃₁ And green light G is green monochromatic image data D _G Pixel group A in which is written ₂ , A ₅ , A ₈ ... A ₂₉ , A ₃₂ The blue light B is blue monochromatic image data D _B Pixel group A in which is written ₃ , A ₆ , A ₉ ... A ₃₀ Respectively.
[0101]
Therefore, the display of each pixel row group of the micromirror display element 13 in the first field is performed by the first pixel row group A. ₁ Is red, second pixel row group A ₂ Is green, third pixel row group A ₃ Blue ... 28th pixel row group A ₂₈ Is red, 29th pixel row group A ₂₉ Is green, the 30th pixel row group A ₃₀ Is blue, 31st pixel row group A ₃₁ Is red, final 32nd pixel row group A ₃₂ Is a green monochrome image.
[0102]
In the second field, as shown in FIG. 11, the first, fourth, seventh,..., 28th and 31st pixel row groups A of the 32 pixel row groups of the micromirror display element 13 are arranged. ₁ , A ₄ , A ₇ ... A ₂₈ , A ₃₁ To the green single-color image data D _G Are written, and the second, fifth, eighth,..., 29th and 32nd pixel row groups A ₂ , A ₅ , A ₈ ... A ₂₉ , A ₃₂ To each of the blue monochromatic image data D _B Are written, and the third, sixth, ninth,..., Thirtieth pixel row groups A ₃ , A ₆ , A ₉ ... A ₃₀ To red monochromatic image data D _R Is written, and the stripe-shaped light beam Sa emitted from the light source device 1a is reflected by the second reflection surface 23b of the rotating mirror 22, and the upper one light beam and the lower three light beams R of the light beam Sa are reflected. , G, and B enter the display area 13a of the micromirror display element 13, and the red light R among the other 32 lights R, G, and B is red monochromatic image data D. _R Pixel group A in which is written ₁ , A ₄ , A ₇ ... A ₂₈ , A ₃₁ And green light G is green monochromatic image data D _G Pixel group A in which is written ₂ , A ₅ , A ₈ ... A ₂₉ , A ₃₂ The blue light B is blue monochromatic image data D _B Pixel group A in which is written ₃ , A ₆ , A ₉ ... A ₃₀ Respectively.
[0103]
Therefore, the display of each pixel row group of the micromirror display element 13 in the second field is performed by the first pixel row group A. ₁ Is green, second pixel row group A ₂ Is blue, third pixel row group A ₃ Is red ... the 28th pixel row group A ₂₈ Is green, 29th pixel row group A ₂₉ Is blue, 30th pixel row group A ₃₀ Is red, the 31st pixel row group A ₃₁ Is green, the final 32nd pixel row group A ₃₂ Is a blue monochromatic image.
[0104]
Further, in the third field, as shown in FIG. 12, of the 32 pixel row groups of the micromirror display element 13, the first, fourth, seventh... 28th and 31st pixel row groups A ₁ , A ₄ , A ₇ ... A ₂₈ , A ₃₁ To each of the blue monochromatic image data D _B Are written, and the second, fifth, eighth,..., 29th and 32nd pixel row groups A ₂ , A ₅ , A ₈ ... A ₂₉ , A ₃₂ To red monochromatic image data D _R Are written, and the third, sixth, ninth,..., Thirtieth pixel row groups A ₃ , A ₆ , A ₉ ... A ₃₀ To the green single-color image data D _G Is written, and the stripe-shaped light beam Sa emitted from the light source device 1a is reflected by the third reflection surface 23c of the rotating mirror 22, and the upper two light beams R and the lower two light beams R of the light beam Sa are reflected. , G and B are incident on the outside of the display area 13a of the micromirror display element 13, and among the other 32 lights R, G and B, the red light R is red monochromatic image data D. _R Pixel group A in which is written ₁ , A ₄ , A ₇ ... A ₂₈ , A ₃₁ And green light G is green monochromatic image data D _G Pixel group A in which is written ₂ , A ₅ , A ₈ ... A ₂₉ , A ₃₂ The blue light B is blue monochromatic image data D _B Pixel group A in which is written ₃ , A ₆ , A ₉ ... A ₃₀ Respectively.
[0105]
Therefore, the display of each pixel row group of the micromirror display element 13 in the third field is performed by the first pixel row group A. ₁ Is blue, second pixel row group A ₂ Is red, third pixel row group A ₃ Green ... 28th pixel row group A ₂₈ Blue, 29th pixel row group A ₂₉ Is red, the 30th pixel row group A ₃₀ Is green, the 31st pixel row group A ₃₁ Is blue, final 32nd pixel row group A ₃₂ Is a red monochrome image.
[0106]
Outgoing light (light reflected in the front direction) R, G, B from the micromirror display element 13 is projected on a projection surface by expanding its light flux by a projection optical system 24. Each pixel row group A ₁ ~ A ₃₂ Are observed as a combined color image of the red, green, and blue monochromatic images.
[0107]
That is, the image projected on the projection plane is a pixel row group A of the micromirror display element 13. ₁ ~ A ₃₂ Is an image in which the colors of the single-color image change in any order of red → green → blue, green → blue → red, blue → red → green for each field. A color image in which the images are combined can be observed.
[0108]
As described above, the display device includes a plurality of pixel row groups A of the micromirror display element 13. ₁ ~ A ₃₂ Are respectively assigned to the dichroic filters 7Ra and 7Ga. Of the striped color panel 6a. Red, green, and blue monochromatic image data D corresponding to the color of 7Ba _R , D _G , D _B Is sequentially written for each field obtained by dividing one frame into three parts, and the monochrome image data for each pixel row group in the same field is alternately changed, and the red color of the stripe color panel 6a is transmitted from the light source device 1a. , Green and blue dichroic filters 7Ra, 7Ga. The direction of the stripe light flux Sa of the red, green, and blue light R, G, and B transmitted through 7Ba is changed in the direction in which the pixel rows of the micromirror display element 13 are arranged, and the red light, green light of the light flux Sa is changed. , Blue light R, G, and B, respectively, to a plurality of pixel row groups A of the micromirror display element 13. ₁ ~ A ₃₂ Out of the plurality of pixel row groups A for each field by causing the micromirror display element 13 to enter a pixel row group in which monochrome image data corresponding to the color of the light is written. ₁ ~ A ₃₂ Are displayed alternately, and a color image in which the single-color images of these colors are combined is observed.
[0109]
In this display device, as described above, the light source device 1a emits red, green, and blue light of sufficient intensity to emit a stripe-shaped light flux Sa in which R, G, and B are arranged. Each pixel row group A of the micromirror display element 13 ₁ ~ A ₃₂ , A red, green, and blue monochromatic image is sequentially displayed with sufficient brightness, and a high-luminance color image can be obtained.
[0110]
In addition, since this display device further includes a projection optical system 24 that projects the light emitted from the micromirror display element 13 onto a projection surface, the display image of the micromirror display element 13 is enlarged and projected onto the projection surface. Can be displayed.
[0111]
In this embodiment, the total number of red, green, and blue lights R, G, and B of the stripe light beam Sa emitted from the light source device 1a and incident on the micromirror display element 13 is calculated by the micromirror display element 13 Since the number of the pixel rows is four more than the number of the pixel rows, as shown in FIGS. 10 to 12, in each of the first to third fields, the four lights R, G, and B are micromirror-displayed. Although the light enters the outside of the display area 13a of the element 13 and is wasted, the other light, R, G, and B, all enter the display area 13a of the micromirror display element 13, so that the light emitted from the light source device 1a. Can be used for display with a high efficiency of about 89%.
[0112]
In addition, in this embodiment, the light source side optical system 20 that causes the light flux Sa emitted from the light source device 1a to enter the micromirror display element 13 uses the number of colors of light of the light flux Sa (three colors of red, green, and blue). ) Is a polygonal cylinder shape in which the number of flat surfaces is an integer number of times continuous in the circumferential direction, and each flat surface corresponding to the number of colors of light is the center of the polygonal cylinder and the flat surface in the polygonal cylinder circumferential direction. The polygons are formed on reflection surfaces 23a, 23b, 23c in which angles θa, θb, θc with respect to a radial line r passing through the center are made different at a ratio corresponding to a pitch of a plurality of pixel row groups of the micromirror display element 13. Since the center of the cylinder is set as a rotation center O, one of the reflection surfaces 23a, 23b, and 23c is provided for each field so that one of the reflection surfaces 23a, 23b, and 23c is rotated so as to face the incident direction of the light beam Sa. By simply rotating the mirror 22, the direction of the light beam Sa emitted from the light source device 1a is changed, and the red, green, and blue lights R, G, and B of the light beam Sa are respectively displayed on the micromirror. The light can be incident on a pixel row group to which monochromatic image data corresponding to the color of the light is written out of the plurality of pixel row groups of the element 13.
[0113]
In the above embodiment, the light source device 1a emits a light flux Sa in which the total number of red, green, and blue lights R, G, and B is four more than the number of pixel rows of the micromirror display element 13. However, of the light beams R, G, and B of the light beam Sa, two light beams on one end side (lower side in FIGS. 10 to 12) are microscopic in any of the first to third fields described above. This is light that enters the outside of the display area 13a of the mirror display element 13 and is wasted.
[0114]
That is, as in this embodiment, the striped luminous flux Sa in which red, green, and blue colored lights R, G, and B are alternately arranged is changed on the micromirror display element 13 in the arrangement direction of the pixel row group. In this case, all the pixel row groups A are provided for each of the first to third fields. ₁ ~ A ₃₂ The number of lights of the light flux Sa required to make the lights R, G, and B incident on the pixel is two more than the number of pixel row groups, and the light more than that shown in FIGS. As described above, any field enters the display area 13a of the micromirror display element 13 and is wasted.
[0115]
Therefore, the light source device 1a emits a striped light beam in which the total number of red, green, and blue lights R, G, and B is at least two or more than the number of pixel rows of the micromirror display element 13. Should be fine.
[0116]
However, when the monochromatic image data written to the pixels of the plurality of pixel rows of the micromirror display element 13 is image data of three colors, the light source device 1a emits red, green, and blue light R, G, It is preferable that the total number of light beams B is 2 to 4 more than the number of pixel rows of the micromirror display element 13 so that the number of light fluxes Sa is emitted. Light R, G, and B of three colors of red, green, and blue are made incident on all the pixel row groups of the micromirror display element 13 to display a monochromatic image on all the pixel row groups, and from the light source device 1a. Light loss can be reduced.
[0117]
In the above-described embodiment, the total pixel row of the micromirror display element 13 is divided into 32 pixel row groups each including 24 pixel rows, and the pixels of these pixel row groups are assigned 3 pixels of red, green, and blue, respectively. Monochromatic image data of a color is sequentially written for each of the first to third fields, and monochromatic image data for each pixel row group in the same field is alternately written. The number of divisions of the total pixel row may be arbitrary, and the number of the red, green, and blue light R, G, and B band lights emitted from the light source device 1a is determined according to the number of the divided pixel row groups. A number that allows the band light of the three colors to be incident on all the pixel rows of the micromirror display element 13 for each field (preferably 2 to 4 more than the number of the pixel rows of the micromirror display element 13). More) Good.
[0118]
Further, in the above embodiment, the stripe-shaped color panel 6a of the light source device 1a is formed in an entire area where the light emitted from the light guide rod 5 is incident, and the dichroic filters 7Ra, 7Ga, and 7Ba are respectively provided. The red, green, and blue dichroic filters 7Ra, 7Ga, and 7Ba are all formed in a width corresponding to the width of a region where the light emitted from the light guide rod 5 is incident. 6a is made larger than in the above embodiment, and among the dichroic filters 7Ra, 7Ga and 7Ba, the light emitted from the light guide rod 5 is colored by the dichroic filters 7Ra, 7Ga and 7Ba in the region where the light is incident. Alternatively, the light may be emitted.
[0119]
In the display devices of the first and second embodiments, the light source devices 1 and 1a emit the striped luminous fluxes S and Sa in which red, green, and blue colored lights R, G, and B are arranged. Thus, monochromatic image data of three colors of red, green, and blue are written in the micromirror display element 13, but the colored light emitted from the light source devices 1 and 1 a and the micromirror display element 13 are written. The monochromatic image data to be written may be, for example, three colored lights of magenta, yellow, and cyan and monochromatic image data. Further, the number of colors of the colored light and the monochromatic image data is not limited to three, but may be two or four. The above may be sufficient.
[0120]
The display devices of the first and second embodiments use the micromirror display element 13 as a display body. The display body has a reflective film on the back side and has a matrix shape in the row and column directions. A reflective liquid crystal display element that displays an image by controlling the reflection of light incident on a plurality of pixels arranged in a matrix may be used.
[0121]
Further, the display may be a transmissive liquid crystal display element that controls transmission of light incident on a plurality of pixels arranged in a matrix to display an image, and in that case, an incident surface of the transmissive liquid crystal display element. A light source device, and a light source side optical system that causes light emitted from the light source device to be incident on the liquid crystal display element, and the light emitted from the liquid crystal display element is provided on the emission surface side of the transmission type liquid crystal display element. A projection optical system for projecting the image on the projection surface may be arranged.
[0122]
Further, the display device of the above embodiment further includes a projection optical system for projecting outgoing light from the display body onto a projection surface, but in the case where the reflective or transmissive liquid crystal display element is used as a display body. May be a direct-view display device in which the projection optical system is omitted and the emission surface of the display body is a display surface.
[0123]
【The invention's effect】
A light source device of the present invention has a light source unit that emits light, an incident end of light, and an exit end of light, and the incident end is arranged to face the light source unit, and guides light incident from the incident end. The light guide rods emitted from the emission end and the transmission wavelength bands are different from each other, among the incident light in the visible light band, the light in the transmission wavelength band is transmitted, and a plurality of colors of light that reflect light in other wavelength bands are reflected. A dichroic filter is provided, and each of these dichroic filters is formed in a corresponding width with a dichroic filter of a plurality of colors within a width of a region where the light emitted from the light guide rod enters. A coloring means disposed so as to face the light guide rod, the light guide rod being disposed between the light source unit and the light guide rod, and converting light emitted from the light source unit into linearly polarized light having the same polarization plane. A polarization conversion element that is incident on an incident end, a polarization beam splitter that is provided at the incident end of the light guide rod, transmits linear polarized light that has passed through the polarization conversion element, and reflects linear polarized light that is orthogonal to the polarization conversion element; The λ / 4 retardation plate provided at the emission end of the rod and providing a を wavelength phase difference between the ordinary light and the extraordinary light of the transmitted light allows the light from the light source unit to be efficiently It is possible to simultaneously emit colored lights of a plurality of colors with sufficient intensity by using well.
[0124]
In the light source device of the present invention, the coloring unit includes a plurality of dichroic filters of a plurality of colors arranged alternately in the circumferential direction on the entire circumference of the rotating plate, and these dichroic filters each emit light from the light guide rod. A dichroic filter of a plurality of colors has a corresponding width within the width of the rotating plate in the radial direction of the incident area, and is formed in a band shape curved in an involute curve along the circumferential direction of the rotating plate, and an outer peripheral portion thereof is formed. It is preferable that a part of the light guide rod is opposed to the light-emitting end, and the center of the color wheel is fixed to the rotation axis. By using the color wheel, colored lights of a plurality of colors having sufficient intensity are arranged. A light beam having a stripe-like shape, in which the position of the colored light of each color changes in the arrangement direction of the colored light of each color with the rotation of the color wheel. Rukoto can.
[0125]
The coloring means may be a striped color panel in which a plurality of linear strip-shaped dichroic filters are alternately arranged in parallel in the width direction and provided in parallel, and are arranged opposite to the emission end of the light guide rod. By using the striped color panel, a striped luminous flux in which colored lights of a plurality of colors having sufficient intensity are arranged can be emitted.
[0126]
The display device of the present invention has a light source unit that emits light, an incident end of light, and an exit end of the light, and is disposed with the incident end facing the light source unit, and guides light incident from the incident end. The light guide rods emitted from the emission end and the entire circumference of the rotating plate have different transmission wavelength bands, and among the incident light in the visible light band, the light in the transmission wavelength band is transmitted, and the light in the other wavelength band is transmitted. Dichroic filters of a plurality of colors that reflect light are provided alternately in the circumferential direction, and each of these dichroic filters has a plurality of dichroic filters within a width in a rotating plate radial direction of a region where light emitted from the light guide rod is incident. The color dichroic filter has a corresponding width, is formed in a band shape curved in an involute curve along the circumferential direction of the rotating plate, and a part of the outer peripheral portion thereof is opposed to the emission end of the light guide rod, During ~ A color wheel fixedly disposed on a rotation axis, and disposed between the light source unit and the light guide rod, and converts the light emitted from the light source unit into linearly polarized light having the same polarization plane. A polarization conversion element that is incident on the incident end of the light guide rod, and a polarization beam splitter that is provided at the incident end of the light guide rod, transmits linearly polarized light that has passed through the polarization conversion element, and reflects linearly polarized light that is orthogonal thereto. A light source device comprising: a λ / 4 phase difference plate provided at an emission end of the light guide rod and providing a phase difference of １ ／ wavelength between ordinary light and extraordinary light of transmitted light;
It has a plurality of pixels arranged in a matrix in the row direction and the column direction, and the row direction is orthogonal to the rotating plate radial direction of a region where the light emitted from the light guide rod of the color wheel of the light source device is incident. A display that is arranged and controls the reflection or transmission of light incident on the plurality of pixels to display an image,
An optical system for causing the plurality of colors of light emitted from the light source device to pass through the dichroic filters of the plurality of colors of the color wheel and to enter the display body;
Monochromatic image data of a plurality of colors corresponding to the colors of the respective dichroic filters of the color wheel are sequentially incident on the pixels of the respective rows of the display body with the rotation of the color wheel. Display driving means for sequentially writing in synchronization with the incident timing of the colored lights of the plurality of colors, so that a single-color image of a plurality of colors is sequentially formed on each pixel row of the display body with sufficient brightness. And a high-luminance color image can be obtained.
[0127]
Further, another display device of the present invention has a light source unit that emits light, an incident end and an exit end of light, the incident end is arranged to face the light source unit, and light enters from the incident end. A light guide rod that guides light and emits light from the emission end, and a plurality of linear dichroic filters of a linear band are alternately arranged in the width direction and provided in parallel with each other, and these dichroic filters are respectively separated from the light guide rod. A plurality of dichroic filters of a plurality of colors formed in a corresponding width within a width of a region on which the outgoing light is incident, and a stripe-shaped color panel arranged and fixed to face an emission end of the light guide rod; and the light source unit. A polarization conversion element disposed between the light guide unit and the light guide rod, the light conversion unit converting the light emitted from the light source unit into linearly polarized light having the same polarization plane, and entering the light into the incident end of the light guide rod. A polarizing beam splitter that is provided at an incident end of the light guide rod, transmits linear polarized light that has passed through the polarization conversion element, and reflects linear polarized light that is orthogonal to the polarized light; A light source device including a λ / 4 phase difference plate that gives a phase difference of １ ／ wavelength between ordinary light and extraordinary light;
A plurality of pixels arranged in a matrix in a row direction and a column direction, wherein the row direction is arranged in parallel with a length direction of a dichroic filter of a plurality of colors of a striped color panel of the light source device; A display body for displaying an image by controlling the reflection or transmission of light incident on the pixels of
One frame is divided into a plurality of single-color image data of a plurality of colors corresponding to the colors of the dichroic filters of the striped color panel, respectively, for each of the pixels of a plurality of pixel rows including a predetermined number of pixel rows of the display. Display driving means for sequentially and monochromatic image data for each pixel row group in the same field and written alternately for each field;
The direction of the luminous flux of the colored light of a plurality of colors emitted from the light source device through the dichroic filters of the plurality of colors of the striped color panel is changed in the direction in which the pixel rows of the display body are arranged, and the plurality of the luminous fluxes are changed. And an optical system for causing each of the colored lights of the colors to be incident on a pixel row group in which monochromatic image data corresponding to the color of the light among the plurality of pixel row groups of the display body is written. In addition, the monochrome images of the plurality of colors are sequentially displayed with sufficient brightness on the plurality of pixel row groups of the display body, and a high-luminance color image can be obtained.
[0128]
In this display device, the optical system that causes the light beam emitted from the light source device to enter the display body has a polygonal cylindrical shape in which flat surfaces of an integral multiple of the number of colors of the light beam are continuous in the circumferential direction. Each flat surface corresponding to the number of colors of light has an angle with respect to a radial line passing through the center of the polygonal tube and the center of the flat surface in the circumferential direction of the polygonal tube according to the pitch of the pixel row group of the display. A configuration in which a rotating mirror is formed on a reflecting surface having a different ratio, and one of the reflecting surfaces is rotated in such a manner that one of the reflecting surfaces faces the incident direction of the light flux for each field, with the center of the polygonal tube as a rotation center. Preferably, with such a configuration, the direction of the light beam emitted from the light source device is changed with a simple control just by rotating the rotating mirror, and light of a plurality of colors of the light beam is respectively transmitted. , The table above Monochrome image data corresponding to the light color of the plurality of pixels Gyogun the body can be incident on the pixel row group to be written.
[0129]
Further, in this display device, for example, monochromatic image data to be written into pixels of a plurality of pixel rows of the display by the display driving means is converted into three-color image data, and the three-color dichroic filter is provided to the light source device. When the light source device is provided with a plurality of striped color panels alternately arranged, the total number of the three colored lights transmitted through the three dichroic filters is greater than the number of the pixel row groups of the display. It is preferable that at least two or more stripe-shaped light beams are emitted. With such a structure, the light of the three colors is applied to all pixel row groups of the display body for each field. Thus, a monochromatic image can be displayed on all the pixel row groups.
[0130]
It is preferable that each of the display devices according to the present invention further includes a projection optical system that projects light emitted from the display body onto a projection surface. Can be enlarged and displayed on the projection surface.
[Brief description of the drawings]
FIG. 1 is a configuration diagram of a display device showing a first embodiment of the present invention.
FIG. 2 is an enlarged side view of a light guide rod and a coloring unit of the light source device according to the first embodiment.
FIG. 3 is a perspective view of the coloring means.
FIG. 4 is a state diagram showing a relationship between a change in a light beam incident on a display body and monochromatic image data written in each pixel row of the display body in the display device of the first embodiment.
FIG. 5 is a diagram of another state.
FIG. 6 is a diagram of another state.
FIG. 7 is a diagram of another state.
FIG. 8 is a configuration diagram of a display device showing a second embodiment of the present invention.
FIG. 9 is an enlarged side view of a coloring unit of the light source device of the display device.
FIG. 10 is a diagram of a first field showing a relationship between writing of monochrome image data on a display for each field and incidence of a light beam on the display in the display device of the second embodiment.
FIG. 11 is a diagram of a second field.
FIG. 12 is a diagram of a third field.
[Explanation of symbols]
1, 1a: light source device, 2: light source unit, 5: light guide rod, 6: color wheel (coloring means), 6a: stripe-shaped color panel (coloring means), 7R, 7G, 7B, 7Ra, 7Ga, 7Ba ... Dichroic filter, 8 motor, 8a rotation axis, 9 polarization conversion element, 10 condensing lens, 11 polarization beam splitter, 12 λ / 4 phase difference plate, 13 micromirror display element (display), 14, 20: light source side optical system, 22: rotating mirror, 23a, 23b, 23c: reflective surface, 16, 24: projection optical system.

Claims (8)

A light source unit that emits light; a light incident end and an emission end; and a light guide that is disposed with the incident end facing the light source unit, guides light incident from the incident end, and emits light from the emission end. The optical rod and the transmission wavelength band are different from each other, and among the incident light in the visible light band, a dichroic filter of a plurality of colors that transmits light in the transmission wavelength band and reflects light in other wavelength bands is provided. Each of these dichroic filters has a dichroic filter of a plurality of colors formed in a corresponding width within a width of a region where light emitted from the light guide rod is incident, and is disposed to face an emission end of the light guide rod. A polarization unit disposed between the light source unit and the light guide rod, for converting light emitted from the light source unit into linearly polarized light having the same polarization plane, and entering the light into the incident end of the light guide rod; A conversion element, a polarization beam splitter that is provided at an incident end of the light guide rod, transmits linearly polarized light that has passed through the polarization conversion element, and reflects linearly polarized light that is orthogonal thereto, and is provided at an output end of the light guide rod. And a λ / 4 retardation plate for providing a 板 wavelength phase difference between the transmitted ordinary light and the extraordinary light. The coloring means is provided with dichroic filters of a plurality of colors alternately arranged in the circumferential direction on the entire circumference of the rotating plate, and these dichroic filters are respectively provided in the radial direction of the rotating plate in a region where the light emitted from the light guide rod is incident. The dichroic filters of a plurality of colors have corresponding widths within the width of the light guide rod, and are formed in a band shape curved in an involute curve along the circumferential direction of the rotating plate, and a part of the outer peripheral portion of the light guide rod is formed. The light source device according to claim 1, wherein the light source device is a color wheel that is arranged to face the emission end and to be fixed at a center to a rotation axis. The coloring means is a stripe-shaped color panel in which dichroic filters of a plurality of linear strips are alternately arranged in parallel in the width direction and provided in parallel, and are arranged to face the emission end of the light guide rod. The light source device according to claim 1. A light source unit that emits light; a light incident end and an emission end; and a light guide that is disposed with the incident end facing the light source unit, guides light incident from the incident end, and emits light from the emission end. The optical rod and the entire circumference of the rotating plate have different transmission wavelength bands, and among incident lights in the visible light band, transmit light in the transmission wavelength band and reflect light in other wavelength bands. The dichroic filters are provided alternately in the circumferential direction, and these dichroic filters correspond to dichroic filters of a plurality of colors, respectively, within a width of a rotating plate radial direction in a region where light emitted from the light guide rod enters. It has a width, is formed in a band shape curved in an involute curve along the circumferential direction of the rotating plate, a part of the outer peripheral portion thereof is opposed to the emission end of the light guide rod, and the center is fixed to the rotating shaft. Distribute Between the light source unit and the light guide rod, and converts the light emitted from the light source unit into linearly polarized light having the same polarization plane and enters the light guide rod at the incident end. A polarization conversion element to be provided, a polarization beam splitter provided at an incident end of the light guide rod, transmitting linearly polarized light transmitted through the polarization conversion element, and reflecting linearly polarized light orthogonal thereto, and an emission end of the light guide rod. A light source device comprising: a λ / 4 phase difference plate that provides a phase difference of １ ／ wavelength between the ordinary light and the extraordinary light of the transmitted light;
It has a plurality of pixels arranged in a matrix in the row direction and the column direction, and the row direction is orthogonal to the rotating plate radial direction of a region where the light emitted from the light guide rod of the color wheel of the light source device is incident. A display that is arranged and controls the reflection or transmission of light incident on the plurality of pixels to display an image,
An optical system for causing the plurality of colors of light emitted from the light source device to pass through the dichroic filters of the plurality of colors of the color wheel and to enter the display body;
Monochromatic image data of a plurality of colors corresponding to the colors of the dichroic filters of the color wheel are sequentially incident on the pixels of each row of the display body, respectively, with the rotation of the color wheel. A display drive unit for sequentially writing the color light in synchronization with the incident timing of the colored lights of the plurality of colors. A light source unit that emits light; a light incident end and an emission end; and a light guide that is disposed with the incident end facing the light source unit, guides light incident from the incident end, and emits light from the emission end. An optical rod and dichroic filters of a plurality of linear strips are alternately arranged in the width direction and provided in parallel with each other, and each of these dichroic filters is set within a width of a region where light emitted from the light guide rod is incident. The dichroic filters of the plurality of colors are formed in corresponding widths, and are arranged between the light source unit and the light guide rod, and a stripe-shaped color panel arranged and fixed to face the emission end of the light guide rod. A polarization conversion element that converts light emitted from the light source unit into linearly polarized light having the same polarization plane and causes the light to enter the incident end of the light guide rod, and is provided at the incident end of the light guide rod. A polarization beam splitter that transmits linearly polarized light that has passed through the polarization conversion element and reflects linearly polarized light that is orthogonal thereto, and is provided at the emission end of the light guide rod, between the ordinary light and the extraordinary light of the transmitted light. A light source device including a λ / 4 retardation plate that provides a 差 wavelength phase difference,
A plurality of pixels arranged in a matrix in a row direction and a column direction, wherein the row direction is arranged in parallel with a length direction of a dichroic filter of a plurality of colors of a striped color panel of the light source device; A display body for displaying an image by controlling the reflection or transmission of light incident on the pixels of
One frame is divided into a plurality of single-color image data of a plurality of colors corresponding to the colors of the dichroic filters of the striped color panel, respectively, for each of the pixels of a plurality of pixel rows including a predetermined number of pixel rows of the display. Display driving means for sequentially and monochromatic image data for each pixel row group in the same field and written alternately for each field;
The direction of the luminous flux of the colored light of a plurality of colors emitted and transmitted from the light source device through the dichroic filters of the plurality of colors of the striped color panel is changed in the direction in which the pixel rows of the display body are arranged, and the plurality of luminous fluxes are changed. And an optical system for causing the colored light of each color to be incident on a pixel row group in which monochromatic image data corresponding to the color of the light among a plurality of pixel row groups of the display body is written. Display device. The optical system that causes the light beam emitted from the light source device to enter the display body has a polygonal cylindrical shape in which flat surfaces of an integral multiple of the color number of the light beam are continuous in the circumferential direction and corresponds to the color number of the light. A reflecting surface in which each flat surface has a different angle from a radial line passing through the center of the polygonal cylinder and the center of the flat surface in the circumferential direction of the polygonal cylinder at a ratio according to the pitch of the pixel row group of the display body. 6. A rotating mirror, wherein one of the reflecting surfaces is rotated for each field so as to face the incident direction of the light beam with respect to the center of the polygonal cylinder as a center of rotation. 3. The projection display device according to 1. The monochromatic image data written to the pixels of the plurality of pixel rows of the display by the display driving means is three-color image data, and the light source device is a stripe in which a plurality of the three-color dichroic filters are alternately arranged. A plurality of colored light beams transmitted through the dichroic filters of the three colors, and a total of three or more colored light beams are emitted from the display body. The display device according to claim 5, wherein: The display device according to claim 4, further comprising a projection optical system that projects light emitted from the display body onto a projection surface.

Images