This application is based upon and claims the benefit of priority from prior Japanese Patent Application No. 2004-360167, filed Dec. 13, 2004, the entire contents of which are incorporated herein by reference.
1. Field of the Invention
The present invention relates to an image display apparatus.
2. Description of the Related Art
There has been known a wobbling technique as one method of obtaining a high-resolution image projection apparatus (image display apparatus) using a display device (LCD, etc.) having limited pixels. According to the wobbling technique, pixel shift is achieved using a light path shift module comprising polarization rotation liquid crystal cell and birefringent plate.
In the foregoing wobbling technique, the shift timing of light (beam) determines in accordance with the on/off of the polarization rotation liquid crystal cell. For this reason, it is important to match the on/off timing of the polarization rotation liquid crystal cell with the display timing of the display device. For example, if TN liquid crystal is used as the polarization rotation liquid crystal cell, the response speed of the polarization rotation liquid crystal cell is not so fast. For this reason, both shift light and non-shift light are emitted from the light path shift module in a change period (rise and fall times) when the foregoing cell changes from off state to on state or from on state to off state. As a result, the light beam also arrives at a pixel position adjacent to a normal pixel position in the preceding change period. For this reason, there is a problem that cross talk and leakage light occurs.
In order to solve the foregoing problem, the following technique is disclosed in JPN. PAT. APPLN. KOKAI Publication No. 2002-281517, for example. According to the technique, red (R) and blue (B) are displayed in the beginning and end periods of one frame while green (G) is displayed in the period between them. By doing so, green (G) having high spectral luminous efficacy is displayed without overlapping with the change period of the polarization rotation liquid crystal cell. Therefore, an influence of the leakage light is reduced. However, red (R) and blue (B) are displayed overlapping with the change period. For this reason, color leakage resulting from the influence of the leakage light is not sufficiently prevented although the leakage light is visually reduced.
Thus, the image display apparatus using the wobbling technique is hard to make high-quality image display due to the leakage light in the change period of the foregoing cell.
Accordingly, an object of the present invention is to provide an image display apparatus, which can reduce an influence of the leakage light to make high-quality image display.
According to a first aspect of the present invention, there is provided an image display apparatus comprising: an image modulation unit generating modulation light modulated in accordance with an image signal; a light path shift unit capable of shifting a light path of the modulation light generated by the image modulation unit; a projection optical unit projecting the modulation light passing through the light path shift unit on a screen; and a correction unit correcting an amount of modulation of the modulation light to be generated by the image modulation unit considering leakage light in a light path excluding a normal light path of the modulation light passing through the light path shift unit.
In the image display apparatus, the image modulation unit generates modulation light with respect to each of colors, and the correction unit corrects an amount of modulation of modulation light with respect to each of the colors.
In the image display apparatus, the correction unit includes: a signal value operation unit correcting a luminance value of an image signal with respect to each of colors considering the leakage light; and a gain operation unit correcting a gain of the image signal corrected by the signal value operation unit so that the maximum luminance value of the image signal corrected by the signal value operation unit does not exceed the maximum luminance value displayable by the image modulation unit.
In the image display apparatus, the correction unit further includes a white balance adjustment unit adjusting a white balance with respect to the image signal having gain corrected by the gain operation unit.
In the image display apparatus, the light path shift unit includes: a polarization rotation liquid crystal cell controlling polarization rotation of the modulation light generated by the image modulation unit; and a birefringence plate on which modulation light from the polarization rotation liquid crystal cell is incident.
In the image display apparatus, the light path shift unit further includes a sensing unit acquiring response characteristic of the polarization rotation liquid crystal cell, and the correction unit changes a value of parameter used for correcting the amount of modulation of modulation light to be generated by the image modulation unit in accordance with the response characteristic acquired by the sensing unit.
In the image display apparatus, the light path shift unit further includes a drive control unit controlling a drive of the polarization rotation liquid crystal cell so that a ratio of leakage light in each light path of the modulation light becomes approximately equal to each other.
In the image display apparatus, TN liquid crystal, STN liquid crystal, vertical alignment liquid crystal or IPS liquid crystal are used for the polarization rotation liquid crystal cell.
In the image display apparatus, quartz, lithium niobate, rutile, calcite, Chile saltpeter or YVO4 is used for the birefringent plate.
In the image display apparatus, the correction unit includes: an image processing unit carrying out image processing for eliminating an influence of the leakage light; and a select switch selecting whether or not the image processing should be made.
In the image display apparatus, the correction unit includes: an image processing unit carrying out image processing for eliminating an influence of the leakage light; and a setting unit setting a level for eliminating an influence of the leakage light in the image processing.
In the image display apparatus, the correction unit includes: an image processing unit carrying out image processing for eliminating an influence of the leakage light; an image characteristic determination unit determining image characteristic of an input image signal; and a setting unit setting a level for eliminating an influence of the leakage light in the image processing in accordance with the image characteristic determined by the image characteristic determination unit.
According to a second aspect of the present invention, there is provided a correction method for an image display apparatus comprising: an image modulation unit generating modulation light modulated in accordance with an image signal; and a light path shift unit capable of shifting a light path of the modulation light generated by the image modulation unit, the method comprising: correcting an amount of modulation of the modulation light to be generated by the image modulation unit considering leakage light in a light path excluding a normal light path of the modulation light passing through the light path shift unit.
In the method, the image modulation unit generates modulation light with respect to each of colors, and wherein correcting the amount of modulation of the modulation light includes correcting an amount of modulation of modulation light with respect to each of the colors.
In the method, correcting the amount of modulation of the modulation light includes: correcting, by a signal value operation unit, a luminance value of an image signal with respect to each of colors considering the leakage light; and correcting, by a gain operation unit, a gain of the image signal corrected by the signal value operation unit so that the maximum luminance value of the image signal corrected by the signal value operation unit does not exceed the maximum luminance value displayable by the image modulation unit.
In the method, correcting the amount of modulation of the modulation light further includes adjusting, by a white balance adjustment unit, a white balance with respect to the image signal having gain corrected by the gain operation unit.
In the method, the light path shift unit includes: a polarization rotation liquid crystal cell controlling polarization rotation of the modulation light generated by the image modulation unit; a birefringence plate on which modulation light from the polarization rotation liquid crystal cell is incident; and a sensing unit acquiring response characteristic of the polarization rotation liquid crystal cell, and correcting the amount of modulation of the modulation light includes changing a value of parameter used for correcting the amount of modulation of modulation light to be generated by the image modulation unit in accordance with the response characteristic acquired by the sensing unit.
In the method, correcting the amount of modulation of the modulation light includes: carrying out image processing for eliminating an influence of the leakage light; and selecting whether or not the image processing should be made.
In the method, correcting the amount of modulation of the modulation light includes: carrying out image processing for eliminating an influence of the leakage light; and setting a level for eliminating an influence of the leakage light in the image processing.
In the method, correcting the amount of modulation of the modulation light includes: carrying out image processing for eliminating an influence of the leakage light; determining image characteristic of an input image signal; and setting a level for eliminating an influence of the leakage light in the image processing in accordance with the determined image characteristic.
Advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention. Advantages of the invention may be realized and obtained by means of the instrumentalities and combinations particularly pointed out hereinafter.
The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate embodiments of the invention, and together with the general description given above and the detailed description of the embodiments given below, serve to explain the principles of the invention.
Embodiments of the present invention will be described below with reference to the accompanying drawings.
The image display apparatus shown in
The correction unit 100 has image processing unit 110 and frame memory 120. An image signal (video signal) inputted to the correction unit 100 is temporarily stored in the frame memory 120. Thereafter, the image processing unit 110 carries out predetermined image processing described later.
The image signal corrected by the correction unit 100 is supplied to the image modulation unit 200. The image modulation unit 200 comprises a LCD, for example, and modulates illumination light from a light source described later in accordance with the image signal.
The illumination light modulated by the image modulation unit 200 is supplied to the light path shift unit 300. The light path shift unit 300 makes a pixel shift using wobbling. The light path shift unit 300 is composed of light path shift module 310 and light path shift module controller 320 controlling the drive of the module 310. The light path shift module 310 comprises polarization rotation liquid crystal cell and birefringent plates (birefringent portion, birefringent material). The light path shift module 310 emits shift light and non-shift light in time sharing.
A modulated light emitted from the light path shift unit 300 is supplied to a screen (not shown) via the projection optical unit 400. Then, an image corresponding to the image in the image modulation unit 200 is enlarged and projected on the screen.
The light path shift module 310 shown in
The polarization rotation liquid crystal cell 311 comprises liquid crystal cell using TN (twisted nematic) liquid crystal. The foregoing liquid crystal cell 311 is configured to control the rotation of the polarized light in accordance with on/off of applied voltage. Specifically, if the applied voltage to the polarization rotation liquid crystal cell 311 is off, an incident light is emitted in a state of being polarized and rotated at an angle of 90°. On the other hand, if the applied voltage to the liquid crystal cell 311 is on, the incident light is emitted without being polarized and rotated. Incidentally, the foregoing liquid crystal cell 311 is not limited to the TN liquid crystal so long as it can control the rotation of the polarized light in accordance with on/off of applied voltage. For example, STN (super twisted nematic) liquid crystal, vertical alignment liquid crystal or IPS (In-Plane Switching) liquid crystal may be used.
The foregoing birefringent plates 312 and 313 separate the incident light into ordinary light (no) and extraordinary light (ne) in accordance with the polarization direction of the incident light. The following anisotropic crystals are used as the birefringent plate. For example, quartz (a-SiO2), lithium niobate (LiNbO3), rutile (TiO2), calcite (CaCO3), Chile saltpeter (NaNO3) and YVO4 are given. The birefringent plate 312 is configured to shift light beam by ½ pixel pitch in the horizontal direction. A vertical polarization light passes through the birefringent plate 312 as an ordinary light without shifted by the plate 312. On the other hand, a horizontal polarization light is shifted to the horizontal direction as an extraordinary light by the birefringent plate 312. The birefringent plate 313 is configured to shift light beam by ½ pixel pitch in the vertical direction. The horizontal polarization light passes through the birefringent plate 313 as an ordinary light without shifted by the plate 313. On the other hand, the vertical polarization light is shifted to the vertical direction as an extraordinary light by the birefringent plate 313.
The operation when on voltage is applied to the polarization rotation liquid crystal cell 311 will be explained below. The image modulation unit 200 emits a polarization light having a horizontal polarization transmission axis as an image light (modulation light). The on voltage is applied to the liquid crystal cell 311; therefore, the polarization light having a horizontal polarization transmission axis passes through the cell 311 without being rotated by the cell 311. The polarization light emitted from the liquid crystal cell 311 is shifted to the horizontal direction by the birefringent plate 312, and passes through there. The polarization light from the birefringent plate 312 passes through the birefringent plate 313 without being shifted by the plate 313. As a result, the image light beam arrives at a pixel position “a” on the screen.
The operation when off voltage is applied to the polarization rotation liquid crystal cell 311 will be explained below. The image modulation unit 200 emits a polarization light having a horizontal polarization transmission axis as an image light (modulation light). The off voltage is applied to the liquid crystal cell 311; therefore, the polarization light having a horizontal polarization transmission axis is rotated at an angle of 90° by the liquid crystal cell 311. Thus, a polarization light having a vertical polarization transmission axis is emitted from the liquid crystal cell 311. The polarization light emitted from the liquid crystal cell 311 passes through the birefringent plate 312 without being shifted by the plate 312. The polarization light from the birefringent plate 312 is shifted to the vertical direction by the birefringent plate 313, and passes through there. As a result, the image light beam arrives at a pixel position “b” on the screen.
As seen from the foregoing description, the on/off state of the liquid crystal cell 311 is switched, and thereby, it is possible to carry out control whether or not the shift operation by birefringent plates 312 and 313 is made. Thus, the on/off state of the liquid crystal cell 311 is switched in synchronous with the modulating timing of the image modulation unit 200. By doing so, display states made on the pixel positions “a” and “b” are synthesized in a time axis direction, as shown in
As seen from
If it is assumed that there is no influence of the leakage light, a luminance value of the image displayed on the pixel position “a” in the n frame is set as V1. Moreover, a luminance value of the image displayed on the pixel position “b” in the n+1 frame is set as V2. In other words, if no leakage light exist and display is made at a luminance value corresponding to the image signal, the luminance values at the pixel positions “a” and “b” are set as V1 and V2. However, the foregoing leakage light is generated in fact. Thus, considering the influence of the leakage light, a luminance value Va at the pixel position “a” in n frame and n+1 frame is expressed by the following equation (1). Likewise, a luminance value Vb at the pixel position “b” in n frame and n+1 frame is expressed by the following equation (2).
Va=V1−αV1−βV1+βV2+αV2 (1)
Vb=V2−αV2−βV2+βV1α+V1 (2)
Namely, if the influence of the leakage light exists, display of the pixel position “a” is made at the luminance value expressed by the equation (1) while display of the pixel position “b” is made at the luminance value expressed by the equation (2).
When determining V1 and V2 from the foregoing equations (1) and (2), the luminance values V1 and V2 are expressed by following equations (3) and (4), respectively.
V1=[(1−α−β)Va−(α+β)Vb]/[(1−α−β)2−(α+β)2] (3)
V2=[(1−α−β)Vb−(α+β)Va]/[(1−α−β)2−(α+β)2] (4)
Considering the influence of the leakage light, the luminance value at the pixel position “a” is Va; on the other hand, the luminance value at the pixel position “b” is Vb. Therefore, the luminance values V1 and V2 are determined from the equations (3) and (4) to supply image signals corresponding to these luminance values V1 and V2 to the image modulation unit. By doing so, it is possible to make proper high-quality image display reducing the influence of the leakage light.
The foregoing matter will be explained below with reference to the block diagram of
If the foregoing correction is made, there exists the case where luminance values V1 and V2 of the corrected image signal exceed the maximum luminance value displayable by the image modulation unit 200. In such a case, gain correction is made so that the maximum luminance value of the corrected image signal does not exceed the maximum luminance value displayable by the unit 200.
When the maximum luminance value displayable by the unit 200 is set as MaxVal, and the maximum luminance value of the corrected image signal is set as Max(Vi), a gain correction coefficient C is expressed by the following equation (5).
C=MaxVal/Max(Vi) (5)
Therefore, luminance values V′1 and V′2 of an image signal supplied to the unit 200 after gain correction are expressed by the following equations (6) and (7), respectively.
V′
1
=C·V
1 (6)
V′2=C·V2 (7)
In the foregoing manner, gain correction is made, and thereby, proper high-quality image display can be obtained even if the corrected luminance value of the image signal exceeds the maximum luminance value displayable by the unit 200.
In the first embodiment, the single chip type image projection apparatus is given as one example. According to the second embodiment, illumination light of red (R), green (G) and blue (B) from an illumination unit is supplied to the image modulation unit 200 in time sharing to display a color image.
A light (illumination) source 510 generates a white light; for example, a discharge lamp is used. The emission side of the light source 510 is provided with a color wheel 520. The color wheel 520 has R filter 521R transmitting R (red) light, G filter 521G transmitting G (green) light and B filter 521b transmitting B (blue) light, as illustrated in
The emission side of the color wheel 520 is provided with polarization conversion device (PS conversion device) 530, illumination optical system 540 and light-quantity adjustable liquid crystal shutter 550. The polarization conversion device 530 converts light having no specific polarization direction from the light source into light having specific polarization direction (vertical direction in this embodiment). The liquid crystal shutter 550 adjusts a ratio of light from each filter of the color wheel 520.
The image modulation unit 200 comprises a transmission type LCD, like the first embodiment. An emission light color is determined in accordance with filters of the color wheel 520. The incident side of the transmission type LCD is provided with a polarization plate (not shown) having a vertical polarization transmission axis. The emission side of the transmission type LCD is provided with a polarization plate (not shown) having a horizontal polarization transmission axis. Therefore, the emission light from the image modulation unit 200 becomes polarization light having a horizontal polarization transmission axis.
The polarization light (modulation light) from the image modulation unit 200 is incident on the light path shift module 310. The structure and operation of the light path shift module 310 is basically the same as
As described in the first embodiment, in the change period when the setting state of the liquid crystal cell 311 is changed, the cell 311 is in an intermediate state between on and off states. For this reason, proper image display is hindered due to the influence of leakage light. According to the second embodiment, the following correction is made to obtain proper image display.
As described in the first embodiment, if it is assumed that there is no influence of leakage light, a luminance value of the R image displayed on the pixel position “a” in the n frame is set as R1. A luminance value of the R image displayed on the pixel position “b” in the n+1 frame is set as R2. However, in fact, leakage light exists; for this reason, the influence of leakage light must be considered. Therefore, a luminance value Ra of the R image displayed on the pixel position “a” in n and n+1 frames and a luminance value Rb of the R image displayed on the pixel position “b” in the same as above are expressed by the following equations (8) and (9), respectively.
Ra=R1−αR1+βR2 (8)
Rb=R2−βR2+αR1 (9)
In other words, if there is an influence of leakage light, the R image is displayed on the pixel position “a” at the luminance value expressed by the equation (8). Simultaneously, the R image is displayed on the pixel position “b” at the luminance value expressed by the equation (9).
Thus, when calculating R1 and R2 based on the foregoing equations (8) and (9), R1 and R2 are expressed by the following equations (10) and (11), respectively.
R1=[(1−β)Ra−βRb]/(1−α−β) (10)
R2=[(1−α)Rb−αRa]/(1−α−β) (11)
The B image is obtained in the same manner as above. Specifically, luminance values Ba and Bb of the B image are expressed by the following equations (12) and (13), respectively.
Ba=B1−βB1+αB2 (12)
Bb=B2−αB2+βB1 (13)
In other words, if there is an influence of leakage light, the B image is displayed on the pixel position “a” at the luminance value expressed by the equation (12). Simultaneously, the B image is displayed on the pixel position “b” at the luminance value expressed by the equation (13).
Thus, when calculating B1 and B2 based on the foregoing equations (12) and (13), B1 and B2 are expressed by the following equations (14) and (15), respectively.
B1=[(1−α)Ba−αBb]/(1−α−β) (14)
B2=[(1−β)Bb−βBa]/(1−α−β) (15)
On the other hand, the influence of leakage light has no need to be considered because the G image is not displayed in the rise and fall change time of the liquid crystal cell 311. That is, G1=Ga, G2=Gb; therefore, no correction is made taking the influence of leakage light into consideration.
As described above, according to the second embodiment, luminance values R1 and R2 are calculated from equations (10) and (11) while luminance values B1 and B2 are calculated from equations (14) and (15). Thus, each image signal corresponding to luminance values R1, R2, B1 and B2 is supplied to the image modulation unit. By doing so, it is possible to make proper high-quality image display reducing the influence of leakage light, like the first embodiment.
If the foregoing correction is made, there exists the case where luminance values R1, R2, B1 and B2 of the corrected image signal exceed the maximum luminance value displayable by the image modulation unit 200, as described in the first embodiment. In such a case, gain correction is made so that the maximum luminance value of the corrected image signal does not exceed the maximum luminance value displayable by the unit 200, like the first embodiment.
When the maximum luminance value displayable by the unit 200 is set as MaxVal, and the maximum luminance value of the image signal of the corrected R and B images is set as Max(Ri, Bi), a gain correction coefficient C is expressed by the following equation (16).
C=MaxVal/Max(Ri,Bi) (16)
Therefore, luminance values R′1, R′2, B′1 and B′2 of an image signal supplied to the unit 200 after gain correction are expressed by the following equations (17) to (20), respectively.
R′1=C·R1 (17)
R′2=C R2 (18)
B′1=C·B1 (19)
B′2=C·B2 (20)
However, gain correction is made with respect to R and B images while it is not made with respect to G image; in this case, there is a possibility that white balance is broken down. Thus, when gain correction is made with respect to the G image, luminance values G′1, and G′2 are expressed by the following equations (21) and (22), respectively.
G′1=C·G1 (21)
G′2=C·G2 (22)
In the foregoing manner, gain correction and white balance adjustment are made, and thereby, proper high-quality image display can be obtained even if the corrected luminance value of the image signal exceeds the maximum luminance value displayable by the unit 200.
In the second embodiment, two-point pixel shift has been given as one example. The third embodiment relates to four-point pixel shift. Therefore, the light path shift module 310 is composed of two polarization rotation liquid crystal cells 311a, 311b, two birefringent plates 312 and 313.
The following is an explanation about the operation of the case where off voltage is applied to liquid crystal cells 311a and 311b. As depicted in
Although a detailed explanation is omitted, when on voltage is applied to liquid crystal cells 311a and 311b, the image light beam arrives at a pixel position “b” on the screen. Moreover, when on voltage is applied to the liquid crystal cell 311a while off voltage is applied to the liquid crystal cell 311b; the image light beam arrives at a pixel position “c” on the screen. Moreover, when off voltage is applied to the liquid crystal cell 311a while on voltage is applied to the liquid crystal cell 311b; the image light beam arrives at a pixel position “d” on the screen.
Therefore, an image having pixels four times as much as the pixels of the image modulation unit 200 is displayed on the screen.
As described in the first embodiment, in the change period when the setting state of the liquid crystal cell is changed, the cell is in an intermediate state between on and off states. For this reason, proper image display is hindered due to the influence of leakage light. According to the third embodiment, the following correction is made to obtain proper image display.
As described in the first and second embodiment, if it is assumed that there is no influence of leakage light, a luminance value of the R image displayed on the pixel position “a” in the n frame is set as R1. A luminance value of the R image displayed on the pixel position “b” in the n+1 frame is set as R2. Moreover, a luminance value of the R image displayed on the pixel position “c” in the n+2 frame is set as R3. A luminance value of the R image displayed on the pixel position “d” in the n+3 frame is set as R4. However, in fact, leakage light exists; for this reason, the influence of leakage light must be considered. Therefore, luminance values Ra, Rb, Rc and Rd of the R image displayed on the pixel positions “a”. “b”, “c” and “d” in n, n+1, n+2 and n+3 frames are expressed by the following equations (23) to (26), respectively.
Ra=R1−αR1+βR2 (23)
Rb=R2−βR2+βR3 (24)
Rc=R3−βR3+αR4 (25)
Rd=R4−αR4+αR1 (26)
The B image is obtained in the same manner as above. Specifically, luminance values Ba to Bd of the B image are expressed by the following equations (27) to (30), respectively.
Ba=B1−βB+αB2 (27)
Bb=B2−βB2+βB3 (28)
Bc=B3−αB3+βB4 (29)
Bd=B4−αB4+αB1 (30)
On the other hand, the influence of leakage light has no need to be considered because the G image is not displayed in the rise and fall change time of the liquid crystal cell. That is, G1=Ga, G2=Gb, G3=Gc, G4=Gd; therefore, no correction is made taking the influence of leakage light into consideration.
Like the first and second embodiments, luminance values R1 to R4 are calculated from equations (23) to (26) while luminance values B1 to B4 are calculated from equations (27) to (30). Thus, each image signal corresponding to luminance values R1 to R4 and B1 to B4 is supplied to the image modulation unit. By doing so, it is possible to make proper high-quality image display reducing the influence of leakage light, like the first and second embodiments.
In the third embodiment, gain correction and white balance adjustment may be made like the second embodiment. In addition, a light source (LED light source) 510 comprising R, G and B light emitting portions 510R, 510G and 510B may be used as seen from
According to the fourth embodiment, the light path shift unit 300 is provided with a light path shift module sensor 330.
The light path shift module sensor 330 includes measurement light source 331, polarization plates 332, 333 and light receiving device 334. Measurement light emitted from the measurement light source 331 is incident on the light receiving device 334 via polarization plate 332, liquid crystal cell 311 and polarization plate 333. The light path shift module sensor 330 is provided, and thereby, the response characteristic of the liquid crystal cell 311 can be measured.
The measurement light from the measurement light source 331 comprising an LED is arranged in one direction in its polarization direction, and thereafter, supplied to the liquid crystal cell 311. The polarization plate 333 is arranged at the position facing the polarization plate 332 via the liquid crystal cell 311. The foregoing polarization plates 332 and 333 are arranged so that their polarization transmission axis is the identical direction. The measurement light passing through the polarization plate 333 is incident on the light receiving device 334 comprising a photo diode. The light receiving device 334 outputs a photoelectric conversion signal in accordance with an amount of received measurement light. The photoelectric conversion signal corresponds to response characteristic of the polarization rotation liquid crystal cell 311.
The response characteristic of the liquid crystal cell 311 changes in accordance with temperature or the like. For this reason, the ratios α and β of the leakage light described in
According to the fourth embodiment, the light path shift module sensor 330 is provided, and thereby, optimum correction operation is made in accordance with a change of response characteristic of the liquid crystal cell 311, that is, a change of parameters α and β. Therefore, it is possible to make proper high-quality image display always and securely reducing an influence of leakage light.
The light path shift module sensor 330 is arranged outside the area where the modulation light modulated by the image modulation unit passes, as seen from
In the fifth embodiment, the light path shift module sensor 330 shown in
As described above, according to the fifth embodiment, the drive of the liquid crystal cell 311 is controlled so that α and β values become approximately equal. By doing so, the relation of α=β is given; therefore, the equations described before are simplified. This serves to simplify the configuration of the correction unit 100 (in particular, image processing unit 110).
According to the foregoing embodiments, the influence of leakage light is reduced as much as possible. However, the influence of leakage light is reduced, and thereby, there is a possibility that contrast is reduced although image fidelity is improved. According to the sixth embodiment, the following configuration is employed to make desired or accurate image display.
According to the present invention, an amount of modulation of the modulation light is corrected considering the leakage light. By doing so, it is possible to make proper high-quality image display reducing the influence of leakage light.
Additional advantages and modifications will readily occur to those skilled in the art. Therefore, the invention in its broader aspects is not limited to the specific details and representative embodiments shown and described herein. Accordingly, various modifications may be made without departing from the spirit or scope of the general inventive concept as defined by the appended claims and their equivalents.
Number | Date | Country | Kind |
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2004-360167 | Dec 2004 | JP | national |