JP4194548B2 - Illumination device and projection display device - Google Patents

Description

  The present invention relates to an illumination device and a projection display apparatus.

As an illuminating device used for a liquid crystal projector or the like, a lighting device such as a super high pressure mercury lamp, a metal halide lamp, a xenon lamp or the like and a parabolic reflector that collimates the irradiation light is generally used. Further, in such an illumination device, in order to reduce unevenness in the amount of light on the irradiation surface, an integration function using a pair of fly-eye lenses (a plurality of illumination areas of a predetermined shape sampled in a plane by an optical device on an illumination object) Some have a function of superimposing and condensing). Furthermore, in recent years, it has been attempted to use a light emitting diode (LED) as a light source (see Patent Documents 1 and 2). Further, a configuration has been proposed in which red light from a red LED, green light from a green LED, and blue light from a blue LED are guided in desired directions using a cross dichroic mirror.
JP-A-10-186507 JP 2002-189263 A

  As shown in FIG. 8, each dichroic mirror in the cross dichroic mirror 102 includes a dichroic mirror 102A that reflects red light from the red LED 100R and a dichroic mirror 102B that reflects blue light from the blue LED 100B. Red light from the red LED 100 </ b> R is reflected by the dichroic mirror 102 </ b> A and guided to the rod integrator 103. Blue light from the blue LED 100 </ b> B is reflected by the dichroic mirror 102 </ b> B and guided to the rod integrator 103. On the other hand, the green light from the green LED 100G passes through the dichroic mirror 102A and the dichroic mirror 102B and is guided to the rod integrator 103. However, the dichroic mirror 102A and the dichroic mirror 102B reflect part of the green light from the green LED 100G, as shown in FIG. That is, in the illumination device having a configuration using the cross dichroic mirror 102, as shown in FIG. 10, there is a problem that the green light is cut and the green light cannot be sufficiently guided forward.

  In view of the above circumstances, an object of the present invention is to provide an illumination device and a projection display device that can minimize the loss of color light from a light source.

  In order to solve the above-described problem, the illumination device according to the present invention sequentially combines a light source that emits red light, a light source that emits green light, a light source that emits blue light, and the three light sources in a time-sharing manner. A lighting control means for lighting, a time-division optical switching element that is provided to guide light from each light source in the same direction or substantially the same direction, and can switch between reflection and transmission according to the presence or absence of voltage application, and each light source An optical integrator that equalizes the intensity of incident light, the time-division optical switching element is provided in a cross shape, and two light sources among the light sources sandwiching the cross-shaped time-division optical switching element The light integrator and another light source are disposed across the other side of the cross-shaped time-division optical switching element, and a voltage is applied to the light emission side of the two light sources. With or without Splitting mirror when it is possible to switch the transmission and reflection I is characterized in that provided on a side surface flush with or substantially flush of the optical integrator. In this section, the above configuration is referred to as a first configuration.

  In order to solve the above-described problem, the illumination device according to the present invention sequentially combines a light source that emits red light, a light source that emits green light, a light source that emits blue light, and the three light sources in a time-sharing manner. A lighting control means for lighting, a time-division optical switching element that is provided to guide light from each light source in the same direction or substantially in the same direction, and can switch between diffraction and transmission according to the presence or absence of voltage application, and each light source An optical integrator that equalizes the intensity of incident light, the time-division optical switching element is provided in a cross shape, and two light sources among the light sources sandwiching the cross-shaped time-division optical switching element The light integrator and another light source are disposed across the other side of the cross-shaped time-division optical switching element, and a voltage is applied to the light emission side of the two light sources. With or without Splitting mirror when it is possible to switch the transmission and reflection I is characterized in that provided on a side surface flush with or substantially flush of the optical integrator. In this section, the above configuration is referred to as a second configuration.

  The illumination device of the present invention includes a light source that emits red light, a light source that emits green light, a light source that emits blue light, and a lighting control unit that sequentially turns on the three light sources in a time-sharing manner, Provided to guide the light from each light source in the same direction or substantially the same direction, the time-division optical switching element capable of switching between reflection and transmission according to the presence or absence of voltage application, and the intensity of light incident from each light source is uniform The time-division optical switching element is provided in a cross shape, and two of the light sources are arranged facing each other with the cross-shaped time-division optical switching element sandwiched therebetween, and The light integrator and another light source are arranged across the other side of the cross-shaped time-division optical switching element, and further, on the light output side of the two light sources, the light wavelength is selected and reflected or Transparent Kuroikkumira wherein the is provided on a side surface flush with or substantially flush of the optical integrator. In this section, the above configuration is referred to as a third configuration.

  The illumination device of the present invention includes a light source that emits red light, a light source that emits green light, a light source that emits blue light, and a lighting control unit that sequentially turns on the three light sources in a time-sharing manner, Provided to guide the light from each light source in the same direction or substantially the same direction, the time-division optical switching element capable of switching diffraction and transmission depending on the presence or absence of voltage application, and the intensity of light incident from each light source is uniform The time-division optical switching element is provided in a cross shape, and two of the light sources are arranged facing each other with the cross-shaped time-division optical switching element sandwiched therebetween, and The light integrator and another light source are arranged across the other side of the cross-shaped time-division optical switching element, and further, on the light output side of the two light sources, the light wavelength is selected and reflected or Transparent Kuroikkumira wherein the is provided on a side surface flush with or substantially flush of the optical integrator. In this section, the above configuration is referred to as a fourth configuration.

  The illumination device of the present invention includes a light source that emits red light, a light source that emits green light, a light source that emits blue light, and a lighting control unit that sequentially turns on the three light sources in a time-sharing manner, A time-division optical switching element that is provided to guide light from each light source in the same direction or substantially in the same direction and can switch between reflection and transmission according to the presence or absence of voltage application, and the intensity of light incident from each light source is uniform. A cylindrical or columnar rod integrator, and a dichroic mirror that selects or reflects or transmits a light wavelength, and the time-division optical switching element is provided on an end surface of the rod integrator, and both sides of the rod integrator are provided. First and second dichroic mirrors that select or reflect the wavelength of light on the surface are arranged, and the rod integrals of the first and second dichroic mirrors are arranged. Two light sources among the light sources are arranged opposite to each other on the side different from the data side, and their principal ray axes are arranged to face the time-division optical switching element. Another light source is arranged on a side surface different from the rod integrator side. In this section, the above configuration is referred to as a fifth configuration.

  In the first to fifth configurations, the other light source may be a light source that emits green light.

  The projection display apparatus of the present invention includes any one of the illumination apparatuses described above, an image display panel provided on the light emitting side of the optical integrator, and the image display panel according to the lighting timing of the light source. A panel driver that supplies video data of each color, and a projection lens that projects video light that has been light-modulated through the video display panel are provided.

  According to the present invention, there is an effect that the loss of color light from the light source can be reduced as much as possible.

  Hereinafter, an illumination device and a projection display apparatus according to an embodiment of the present invention will be described with reference to FIGS.

  FIG. 1 is a diagram showing an optical system of a single-plate projection display apparatus 6 according to this embodiment. The projection display apparatus 6 includes three LED arrays 1R, 1G, and 1B (hereinafter, the symbol “1” is used to indicate each LED array without specifying it). Each LED array 1 has a structure in which LEDs (light emitting diodes) are arranged in an array. The aspect ratio of each LED array 1 may match or substantially match the aspect ratio of the liquid crystal display panel 4. The LED array 1R emits red light, the LED array 1G emits green light, and the LED array 1B emits blue light. The LED array 1R, the LED array 1G, and the LED array 1B are sequentially lighted in a time division manner by a lighting control circuit (not shown). Note that the amount of light increases when pulsed lighting is performed rather than continuous lighting.

  On the light incident side of the rod integrator 3, a cross-shaped time division mirror (time division optical switching element) for guiding the light from each LED array in the same direction or substantially the same direction (in this case, the end face of the rod integrator 3) 2 is provided. The LED array 1R and the LED array 1B are arranged to face each other with the cross-shaped time division mirror 2 in between. A rod integrator 3 and an LED array 1G, which is another light source, are arranged with the other side of the cross-shaped time division mirror 2 interposed therebetween.

  A time division mirror (reflecting means) 11 is provided on the light emitting side of the LED array 1R so as to be flush with or substantially flush with the side surface of the rod integrator 3, and a time division mirror (reflection) is provided on the light emitting side of the LED array 1B. Means) 12 is provided flush with or substantially flush with the side surface of the rod integrator 3. The time division mirrors 11 and 12 transmit light (red light and blue light) from the LED arrays 1R and 1B out of the LED arrays 1R, 1G and 1B, while light (green light) from the LED array 1G is transmitted. It becomes a reflection means to reflect.

  A liquid crystal display panel 4 is provided on the light exit side of the rod integrator 3. The liquid crystal display panel 4 has a structure without a color filter. A liquid crystal display panel driver (not shown) supplies video signals of each color to the liquid crystal display panel 4 in synchronization with the timing when the LED arrays 1R, 1G, and 1B are sequentially turned on in a time division manner as described above.

  The light (image light) modulated by being transmitted through the liquid crystal display panel 4 is enlarged and projected by the projection lens 5 and projected and displayed on a screen (not shown).

The cross-shaped time-division switching mirror 2 described above includes a time-division mirror 2A and a time-division mirror 2B, which are time-division optical switching elements, arranged in a cross shape. For example, the time division mirror 2A is divided into two parts and is provided so as to sandwich the time division mirror 2B. Alternatively, as shown in FIG. 2, two time division mirrors 2A ₁ and 2A ₂ and two time division mirrors 2B ₁ and 2B ₂ are used, and the corners of each of these four time division mirrors are determined. You may make it cross-arranged close.

  The cross-shaped time-division switching mirror 2 and the time-division mirrors 11 and 12 can be switched between reflection and transmission depending on the presence or absence of voltage application, and are configured using DigiLens (registered trademark) that is a switching diffraction element, for example. (See Japanese Patent Application Publication No. 2002-520648 (refer to paragraphs “0008” and “0009” in particular) and Japanese Patent Application Publication No. 2002-525646). The cross-shaped time division mirror 2 and the time division mirrors 11 and 12 are controlled by a mirror control circuit (not shown). This mirror control circuit makes the time division mirror reflective when a predetermined light source is lit (applied or non-applied voltage), and transmits through the time division mirror when another predetermined light source is lit (No voltage application or application). The contents of control in this mirror control circuit (reflection / transmission switching timing of the time division mirror) will be described later.

  If the switching diffraction element is suitable for P-polarized light, for example, light may be aligned with P-polarized light before entering the time-division switching mirror. Such a configuration will be described later.

  The rod integrator 3 has a rectangular tube structure (hollow structure) whose inner surface is a mirror surface, or a square columnar structure (glass rod). The aspect ratio of the rod integrator 3 matches or substantially matches the aspect ratio of the liquid crystal display panel 4. Since the rod integrator 3 reflects each color light from each LED array 1 on the inner surface of the rod and guides it to the liquid crystal display panel 4, the light intensity distribution of each color light is made substantially uniform on the liquid crystal display panel 4. In addition, you may change the magnitude | size of the entrance part and exit part of a square opening not only in a square pillar (cylinder).

  FIG. 3 shows lighting control of the LED arrays 1R, 1G, and 1B, reflection / transmission switching control of the time division mirror 2A and the time division mirror 2B constituting the cross-shaped time division mirror 2, and reflection of the time division mirrors 11 and 12. / Shows the contents of transparent switching control. In this figure, the lighting of the LED is shown in white, and the turning off is shown in black. The reflection state in the time division mirror is indicated by a solid line, and the transmission state is indicated by a dotted line.

  As shown in FIG. 3A, when the LED array 1R is turned on, the time division mirror 2B and the time division mirror 11 are set in a transmission state. The time-division mirror 2A is in a reflective state. The red light from the LED array 1 </ b> R is reflected by the time division mirror 2 </ b> A and guided into the rod integrator 3. The time division mirror 12 is in a transmissive state in the figure, but may be in a reflective state.

  As shown in FIG. 3B, when the LED array 1G is turned on, the time division mirror 2A and the time division mirror 2B are set in a transmission state. The time division mirrors 11 and 12 are in a reflective state. The green light from the LED array 1G passes through the time division mirror 2A and the time division mirror 2B and is guided to the rod integrator 3. As described above, when green light is emitted, both the time division mirror 2A and the time division mirror 2B are in a transmission state, so that it is possible to avoid the loss of green light that tends to occur in the conventional structure including the cross dichroic mirror. . Further, when the time division mirrors 11 and 12 are in the reflecting state, the green light is reflected by the time division mirrors 11 and 12, and for the green light, the time division mirrors 11 and 12 serve as a rod integrator. As a result, the uniformity of the light intensity on the exit surface of the rod integrator 3 is improved.

  As shown in FIG. 3C, when the LED array 1B is turned on, the time division mirror 2A and the time division mirror 12 are set to the transmission state. The time division mirror 2B is in a reflective state. The blue light from the LED array 1B is reflected by the time division mirror 2B and guided into the rod integrator 3. The time division mirror 11 is in a transmissive state in the figure, but may be in a reflective state.

  In the above configuration example, the cross-shaped time-division mirror 2 is provided as the time-division optical switching element. However, the configuration is not limited thereto, and a cross-shaped time-division diffraction element can also be used as the time-division optical switching element. This cross-shaped time-division diffraction element can be configured using DigiLens (registered trademark), which is the switching diffraction element described above.

  FIG. 4 shows an example of control when the cross-shaped time-division diffractive element 2 ′ is used, that is, the lighting control of the LED arrays 1R, 1G, and 1B, and the time-division diffractive element 2 constituting the cross-shaped time-division diffractive element 2 ′. The contents of the diffraction / transmission switching control of 'A and the time division diffraction element 2'B and the reflection / transmission switching control of the time division mirrors 11 and 12 are shown. In this figure as well, the lighting of the LED is shown in white, and the turning off is shown in black. Further, the diffraction states of the time-division diffraction elements 2'A and 2'B are indicated by solid lines, and the transmission state is indicated by dotted lines. The reflection state at the time division mirrors 11 and 12 is indicated by a solid line, and the transmission state is indicated by a dotted line.

  As shown in FIG. 4A, when the LED array 1R is turned on, the time division diffractive element 2′B and the time division mirror 11 are set in a transmission state. The time division diffraction element 2′A is in a diffraction state. The red light from the LED array 1 </ b> R is diffracted by the time division diffraction element 2 ′ A and guided into the rod integrator 3. The time division mirror 12 is in a transmissive state in the figure, but may be in a reflective state.

  As shown in FIG. 4B, when the LED array 1G is turned on, the time-division diffractive elements 2′A and 2′B are set in a transmissive state. The time division mirrors 11 and 12 are in a reflective state. The green light from the LED array 1G passes through the time division diffraction elements 2′A and 2′B and is guided to the rod integrator 3. As described above, when green light is emitted, both the time division diffractive element 2'A and the time division diffractive element 2'B are in the transmission state, and thus the loss of green light that tends to occur in the conventional structure including the cross dichroic mirror. Can be avoided. Further, when the time division mirrors 11 and 12 are in the reflecting state, the green light is reflected by the time division mirrors 11 and 12, and for the green light, the time division mirrors 11 and 12 serve as a rod integrator. As a result, the uniformity of the light intensity on the exit surface of the rod integrator 3 is improved.

  As shown in FIG. 4C, when the LED array 1B is turned on, the time division diffractive element 2′A and the time division mirror 12 are set in a transmission state. The time division diffraction element 2′B is in a diffraction state. The blue light from the LED array 1B is diffracted by the time-division diffractive element 2′B and guided into the rod integrator 3. The time division mirror 11 is in a transmissive state in the figure, but may be in a reflective state.

  FIG. 5 shows another configuration example. In this configuration, a dichroic mirror 21 is provided instead of the time division mirror 11 and a dichroic mirror 22 is provided instead of the time division mirror 12 in the configuration of FIG. The dichroic mirror 21 transmits red light and reflects other color light. The dichroic mirror 22 transmits blue light and reflects other color light. In such a configuration, the above-described mirror control circuit only needs to control the cross-shaped time division mirror 2 (time division mirror 2A and time division mirror 2B).

  As shown in FIG. 5A, when the LED array 1R is turned on, the time-division mirror 2B is set in a transmission state. The time-division mirror 2A is in a reflective state. The red light from the LED array 1R passes through the dichroic mirror 21, is reflected by the time division mirror 2A, and is guided into the rod integrator 3.

  As shown in FIG. 5B, when the LED array 1G is turned on, both the time division mirror 2A and the time division mirror 2B are set in a transmission state. The green light from the LED array 1G passes through the time division mirror 2A and the time division mirror 2B and is guided to the rod integrator 3. As described above, when green light is emitted, both the time division mirror 2A and the time division mirror 2B are in a transmission state, so that it is possible to avoid the loss of green light that tends to occur in the conventional structure including the cross dichroic mirror. . Further, green light is reflected by the dichroic mirrors 21 and 22, and the dichroic mirrors 21 and 22 serve as a rod integrator for the green light, so that the light intensity is uniform on the exit surface of the rod integrator 3. Will improve.

  As shown in FIG. 5C, when the LED array 1B is turned on, the time-division mirror 2A is set in the transmission state. The time division mirror 2B is in a reflective state. Blue light from the LED array 1B passes through the dichroic mirror 22, is reflected by the time division mirror 2B, and is guided into the rod integrator 3.

  The configuration using the dichroic mirrors 21 and 22 described above can also be applied to the configuration shown in FIG. 4 (configuration using the cross-shaped time division diffraction element 2 ′). 3, 4, and 5, the other side of the cross-shaped time-division mirror 2 or the cross-shaped time-division diffractive element 2 ′ (the side where the time-division mirrors 11 and 12 are not provided, that is, FIG. 1, mirrors may be arranged on the upper and lower sides of the cross-shaped time-division mirror 2. Further, in the configuration shown in FIGS. 3, 4, and 5, an integrator including a pair of fly-eye lenses may be used instead of the rod integrator 3.

  FIG. 6 shows another configuration example. In this configuration, a time division mirror 30 is provided as a time division optical switching element on the end surface (light incident surface) of the rod integrator 3. The time division mirror 30 guides the light from the LED arrays 1R and 1B in the same direction or substantially the same direction (light emission side of the rod integrator 3). An LED array 1G is provided on the time division mirror 30. In this configuration example, the dichroic mirrors 21 and 22 are provided on the side surface of the rod integrator 3 on the side close to the end surface. An LED array 1R is provided on the dichroic mirror 21, and an LED array 1B is provided on the dichroic mirror 22. The dichroic mirrors 21 and 22 and the LED arrays 1R and 1B do not necessarily have to be provided to face each other. The LED arrays 1R and 1B are arranged so that the principal ray axis faces the end face (light incident face). The mirror control circuit controls only the time division mirror 30 described above.

  When the hollow rod integrator 3 whose inner surface is a mirror surface is used, the portion where the dichroic mirrors 21 and 22 are disposed is not a mirror surface. Even when a columnar rod integrator is used, a position where the dichroic mirrors 21 and 22 are arranged is set so that light emitted from the LED array easily enters the rod.

  As shown in FIG. 6A, when the LED array 1R is turned on, the time-division mirror 30 is in a reflective state. The red light from the LED array 1R passes through the dichroic mirror 21, enters the rod integrator 3, is reflected by the time-sharing mirror 30 provided on the end face, and is repeatedly reflected in the rod integrator 3. 3 is emitted from the exit surface. The red light is reflected back within the rod integrator 3 and the number of reflections increases, so that the uniformity of the light intensity on the exit surface of the rod integrator 3 is improved.

  As shown in FIG. 6B, when the LED array 1G is turned on, the time-division mirror 30 is set in a transmission state. Green light from the LED array 1 </ b> G enters the rod integrator 3. There is nothing to block this green light, so there is almost no loss of green light. Further, the green light is reflected by the dichroic mirrors 21 and 22.

  As shown in FIG. 6C, when the LED array 1B is turned on, the time division mirror 30 is in a reflective state. The blue light from the LED array 1B passes through the dichroic mirror 22 and enters the rod integrator 3, is reflected by the time-sharing mirror 30 provided on the end face, and is repeatedly reflected in the rod integrator 3. 3 is emitted from the exit surface. The blue light is reflected back in the rod integrator 3 and the number of reflections increases, so that the uniformity of the light intensity on the exit surface of the rod integrator 3 is improved.

  FIG. 7 shows a configuration example in which the polarization conversion device 7 is provided on the light emitting side of the LED array 1. The basic unit of the polarization conversion device 7 (corresponding to the size of the light emission part of each LED) is composed of two polarization beam splitters (PBS) 71 and 71 and one of the polarization beam splitters 71 on the light emission side. And a phase difference plate (1 / 2λ plate) 72 disposed on the substrate. The polarization separation film of each polarization beam splitter 71 passes the P-polarized light and changes the optical path of the S-polarized light by 90 °. The S-polarized light whose optical path has been changed is reflected by the adjacent polarization separation film and is emitted through the phase difference plate 72. Since the S-polarized light is converted into P-polarized light by the retardation plate 72 and emitted, in this case, the light is substantially aligned with the P-polarized light.

  Further, a polarization conversion device may be provided on the light exit side of the rod integrator 3. In this case, the size of the light emitting part of the polarization conversion device is twice the size of the light emitting part of the rod integrator 3. Accordingly, it is desirable that the overall shape of the light emitting part of the polarization conversion device substantially matches the aspect ratio of the liquid crystal panel. In this case, assuming that the aspect ratio of the liquid crystal panel is A: B, the aspect ratio of the light emitting portion of the rod integrator 3 is, for example, A: B / 2. In addition, when the integrator including the pair of fly-eye lenses described above is used, a polarization conversion device can be provided on the light exit side.

  In the configuration example described above, the LED array 1 may include a collimating lens. For example, the LED array 1 can be formed by arranging LED chips in an array and arranging lens cells (for example, for parallel light) on the light emission side of each LED chip by a mold or the like. . Moreover, it is good also as a structure which provides one LED as each color light source.

  In the above configuration example, the projection display apparatus 6 includes the transmissive liquid crystal display panel 4. However, the present invention is not limited to this, and a reflective liquid crystal panel may be used. It is also possible to use a display panel of a type that individually drives a micromirror serving as a pixel. The solid-state light emitting element is not limited to a light emitting diode (LED), and organic / inorganic electroluminescence can be used.

It is the perspective view which showed schematic structure of the projection type video display apparatus of embodiment of this invention. It is explanatory drawing which showed the structural example of the cross-shaped time division | segmentation mirror. It is explanatory drawing of the illuminating device of embodiment of this invention used with the projection type video display apparatus of FIG. It is explanatory drawing of the other illuminating device of embodiment of this invention. It is explanatory drawing of the other illuminating device of embodiment of this invention. It is explanatory drawing of the other illuminating device of embodiment of this invention. It is explanatory drawing of the light source provided with the polarization converter. It is explanatory drawing of the conventional illuminating device. It is explanatory drawing which showed the conventional problem. It is explanatory drawing which showed the conventional problem.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 LED array 2 Cross-shaped time division mirror 2 'Cross-shaped time division diffraction element 3 Rod integrator 4 Liquid crystal display panel 11 Time division mirror 12 Time division mirror 21 Dichroic mirror 22 Dichroic mirror 30 Time division mirror

Claims (7)

A light source that emits red light, a light source that emits green light, a light source that emits blue light,
Lighting control means for sequentially lighting the three light sources in a time-sharing manner;
A time-division optical switching element that is provided to guide light from each light source in the same direction or substantially in the same direction, and can switch between reflection and transmission according to the presence or absence of voltage application;
An optical integrator that equalizes the intensity of light incident from each of the light sources, and
The time-division optical switching element is provided in a cross shape, and two of the light sources are arranged facing each other across the cross-shaped time-division optical switching element and the cross-shaped time-division optical switching element The light integrator and another light source are arranged with the light source side interposed therebetween, and on the light emission side of the two light sources, a time division mirror capable of switching between reflection and transmission according to the presence or absence of voltage application is provided for the light. An illumination device, wherein the illumination device is provided flush or substantially flush with a side surface of the integrator. A light source that emits red light, a light source that emits green light, a light source that emits blue light,
Lighting control means for sequentially lighting the three light sources in a time-sharing manner;
A time-division optical switching element that is provided to guide light from each light source in the same direction or substantially in the same direction, and that can switch between diffraction and transmission according to the presence or absence of voltage application;
An optical integrator that equalizes the intensity of light incident from each of the light sources, and
The time-division optical switching element is provided in a cross shape, and two of the light sources are arranged facing each other across the cross-shaped time-division optical switching element and the cross-shaped time-division optical switching element The light integrator and another light source are arranged with the light source side interposed therebetween, and on the light emission side of the two light sources, a time division mirror capable of switching between reflection and transmission according to the presence or absence of voltage application is provided for the light. An illumination device, wherein the illumination device is provided flush or substantially flush with a side surface of the integrator. A light source that emits red light, a light source that emits green light, a light source that emits blue light,
Lighting control means for sequentially lighting the three light sources in a time-sharing manner;
A time-division optical switching element that is provided to guide light from each light source in the same direction or substantially in the same direction, and can switch between reflection and transmission according to the presence or absence of voltage application;
An optical integrator that equalizes the intensity of light incident from each of the light sources, and
The time-division optical switching element is provided in a cross shape, and two of the light sources are arranged facing each other across the cross-shaped time-division optical switching element and the cross-shaped time-division optical switching element The light integrator and another light source are disposed with the light source side interposed therebetween, and a dichroic mirror that selectively reflects or transmits a light wavelength is provided on the side of the light integrator on the light emission side of the two light sources. The lighting device is provided so as to be flush or substantially flush with each other. A light source that emits red light, a light source that emits green light, a light source that emits blue light,
Lighting control means for sequentially lighting the three light sources in a time-sharing manner;
A time-division optical switching element that is provided to guide light from each light source in the same direction or substantially in the same direction, and that can switch between diffraction and transmission according to the presence or absence of voltage application;
An optical integrator that equalizes the intensity of light incident from each of the light sources, and
The time-division optical switching element is provided in a cross shape, and two of the light sources are arranged facing each other across the cross-shaped time-division optical switching element and the cross-shaped time-division optical switching element The light integrator and another light source are disposed with the light source side interposed therebetween, and a dichroic mirror that selectively reflects or transmits a light wavelength is provided on the side of the light integrator on the light emission side of the two light sources. The lighting device is provided so as to be flush or substantially flush with each other. A light source that emits red light, a light source that emits green light, a light source that emits blue light,
Lighting control means for sequentially lighting the three light sources in a time-sharing manner;
A time-division optical switching element that is provided to guide light from each light source in the same direction or in substantially the same direction, and can switch between reflection and transmission according to the presence or absence of voltage application;
A cylindrical or columnar rod integrator that equalizes the intensity of light incident from each light source; and
A dichroic mirror that selects or reflects or transmits light wavelength;
The time-division optical switching element is provided on an end surface of the rod integrator, and first and second dichroic mirrors that select and reflect or transmit light wavelengths are disposed on both side surfaces of the rod integrator. Of the light sources, two light sources are arranged to face each other on a side surface different from the rod integrator side of the dichroic mirror, and their principal ray axes are arranged to face the time-division optical switching element. An illumination device, wherein another light source is arranged on a side surface different from the rod integrator side of the optical switching element. 6. The lighting device according to claim 1, wherein the other light source is a light source that emits green light. 7. The lighting device according to claim 1, a video display panel provided on a light emitting side of the light integrator, and video data of each color are supplied to the video display panel according to a lighting timing of the light source. And a projection lens that projects image light that has been light-modulated through the image display panel.

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