ES2391493T3 - Projection display - Google Patents

Abstract

A projection display comprising: a light valve (2); a light source (3a) that generates light applied to said light valve (2); an integrating lens (4) provided on an optical path with an optical axis between said light source (3a) and said lens valve (2) and which unifies a distribution of light illumination applied from said light source (3a) to said light valve (2); and a mechanism (9) for controlling the amount of light provided in said optical path and including a pair of light shielding bodies (9B, 9T) arranged on opposite sides of the optical axis c, each light shielding body (9B, 9T being) ) rotatably arranged around an axis of rotation to thereby adjust the amount of light passing from said light source (3a) to said light valve (2), the degiro axes arranged parallel to each other and orthogonal to the axis optical c, in which each of said light shielding bodies is shaped like a plate, and in the four thickness of said light shielding bodies (9B, 9T) it is reduced at its tips so that the shielding bodies are shaped of light (9B, 9T) have sharp edge tips on their side of the optical axis

Description

Projection display

Background of the invention

Field of the Invention

The present invention relates to a projection display with a light quantity control mechanism to adjust the amount of light applied to a light valve that responds to a video signal.

Description of the prior art

A projection display may have difficulties in ensuring high contrast because the projected dark images displayed are not dark enough due to a light leakage of several optical elements in an optical system such as an optical guidance system and a lens projection and due to the parasitic light (unnecessary light) caused by the optical elements. In particular for the projection of images on a screen in a dark room, insufficient darkness of the dark images projected on the screen provides the viewer with the impression of a low contrast. Especially in projection displays that use liquid crystal light valves, although liquid crystal light valves block transmitted light in response to the polarization property of light, complete blocking of transmitted light is difficult and there is also a limit on corrective actions taken by the processing of video signals, therefore a contrast enhancement is required.

As a measure to solve this problem, a flat light shielding plate is provided between a first and a second lens array and is rotated in response to a video signal to control the amount of light applied to a light valve and from this improve the contrast of an image projected on a screen or similar (for example, see WO2005 / 026835).

In WO2005 / 026835, in the case where the light shield plate has a rectangular plane at its tip in a vertical direction with respect to the light shield plate, if the tip of the light shield plate is in the proximity of the first lens array and in a position of the center of the curvature of the second lens array in the direction of rotation of the light shielding plate, the rectangular plane of the light shielding plate is displayed on a valve of light. This undesirably causes a linear irregularity of the illumination in the light valve in a direction perpendicular to the direction of rotation and the direction of the optical axis. It is also difficult to provide a satisfactory contrast depending on the shape of the tip of the light shielding plate.

Document US2006 / 0050249 A1 describes a projector apparatus comprising a light quantity control apparatus having control plates for the amount of light formed by perforating a thin metal plate. Said light quantity control apparatus is configured to provide a uniform opening from a center of the light path to the right and left sides.

Summary of the invention

An object of the invention is to provide a projection display that achieves continuous control of the amount of light easily and without causing irregularity of illumination of the light applied to a light valve that responds to a video signal, thereby allowing a constant image display with satisfactory contrast.

The object of the present invention is solved by the projection display according to claim 1. Advantageous developments of the projection viewer are offered in the dependent claims.

These and other objects, features, aspects and advantages of the invention will become apparent in the following detailed description of the invention when taken in conjunction with the accompanying drawings.

Brief description of the drawings

Figure 1 is a block diagram of an optical lighting system in a projection display according to a first example of the invention; Figure 2 is a block diagram of a polarization conversion element according to the first example. of the invention; Figures 3A and 3B show examples of the shapes of a turning mechanism according to the first example of the invention; Figures 4A and 4B show the rotation of the rotation mechanism according to the first example of the invention; Figure 5 shows the relationship between the angle of rotation and the relative percentage of the amount of light in cases wherein the turning mechanism has the shapes of Figures 3A and 3B according to the first example of the invention; Figures 6A and 6B show the z-direction position of the tip of the turning mechanism when the percentage relative of the amount of light is 20% according to the first example of the invention;

Figure 7 shows a light illumination distribution applied to a light valve when the rotation mechanism in the form of Figure 3B provides a complete light block according to the first example of the invention; Figure 8 shows the relationship between the angle of rotation and the relative percentage of the amount of light in the case where the light shielding bodies have no cut according to the first example of the invention; Figure 9 shows light source images in the vicinity of a second lens array according to the first example of the invention; Figure 10 shows an example of the shape of the turning mechanism according to the first example of the invention; Figure 11 shows the relationship between the angle of rotation and the relative percentage of the amount of light in the case where the rotation mechanism is in the form of Figure 10 according to the first example of the invention; Figure 12 shows the light path with respect to the shape of the turning mechanism according to the first example of the invention; Figures 13A and 13B show the light paths when the rotation mechanism has a smaller dimension than the lens matrices according to the first example of the invention; Figure 14 shows the light paths when reverse ray tracing is carried out from the center of the light valve according to the first example of the invention; Figures 15A and 15B show the rotation position of the rotation mechanism when viewed on the light valve according to the first example of the invention; Figures 16A and 16B show the rotation position of the rotation mechanism when viewed on the light valve according to the first example of the invention; Figures 17A and 17B show distributions of light illumination applied to the light valve according to the first example of the invention; Figure 18 shows a light illumination distribution applied to the light valve according to the first example of the invention; Figure 19 shows the relative percentage of the amount of light on the axes and of Figures 17A, 17B and 18 according to the first example of the invention; Fig. 20 is a block diagram of an optical lighting system in a projection display according to a preferred embodiment of the invention; Figures 21A and 21B show the rotation position of the rotation mechanism when viewed on the light valve according to the preferred embodiment of the invention; Figures 22A and 22B show the rotation position of the rotation mechanism when viewed on the light valve according to the preferred embodiment of the invention; Figures 23A and 23B show distributions of light illumination applied to the light valve according to the preferred embodiment of the invention; Figure 24 shows the relative percentage of the amount of light on the axes and of figures 23A and 23B according to the preferred embodiment of the invention; Figures 25A and 25B show the shape of the tip of the turning mechanism according to the preferred embodiment of the invention; Figure 26 is a block diagram of an optical lighting system in a projection display according to the further preferred embodiment of the invention; Figure 27 shows the incident light paths on the light valve according to the further preferred embodiment of the invention; Figures 28A and 28B show the light paths that pass through the second lens array and the polarization conversion element according to the further preferred embodiment of the invention; Figure 29 shows the relationship between the contrast and the angle of incidence of the light applied to the light valve according to the further preferred embodiment of the invention; Figure 30 shows an example of the shape of the turning mechanism according to the further preferred embodiment of the invention; Figure 31 shows the amount of light passing through each cell in the second lens array 4b according to the further preferred embodiment of the invention; Figure 32 shows the paths of light emitted from a light source 3 according to the further preferred embodiment of the invention; Figure 33 shows a lighting distribution of the light applied to the light valve according to the further preferred embodiment of the invention; Figure 34 shows an example of the shape of the turning mechanism according to the further preferred embodiment of the invention; Figure 35 shows the relationship between the angle of rotation and the relative percentage of the amount of light in the case where the rotation mechanism is in the form of Figure 30 according to the further preferred embodiment of the invention; Figure 36 shows an example of the shape of the turning mechanism according to the further preferred embodiment of the invention; Figure 37 shows the relationship between the angle of rotation and the relative percentage of the amount of light in the case where the rotation mechanism is in the form of Figure 35 according to the further preferred embodiment of the invention; and Figure 38 shows an example of the shape of the turning mechanism according to the further preferred embodiment of the invention;

Description of preferred embodiments

Preferred embodiments of the invention are described below with reference to the drawings

'First example'

Figure 1 is a block diagram of an optical lighting system 1 in a projection display according to a first example of the invention. As shown in Figure 1, the optical lighting system 1 includes an integrating lens 4 between a light source system 3 and a light valve 2, a polarization conversion element 5, a condensing lens 6, a lens of field 7, and a polarization plate 8. The projection display according to the first example of the invention also includes a projection lens (not shown) to project light emitted from the light valve 2 onto a screen. The light valve 2 is provided on each of the optical paths of R, G and B and the optical lighting system 1 shown in Figure 1 is a representative example of any of these optical paths of R, G, and B.

The light valve 2 according to the preferred embodiments of the invention is a liquid crystal light valve, but in the case of using lens arrays, there may be other display devices such as a digital micromirror device (DMD) and a device of reflection display by liquid crystal.

The light source system 3 is configured to apply light to the light valve 2 and includes a light source 3a and a reflective mirror 3b that reflects the light emitted by the light source 3a to radiate the integrating lens 4. The source of light 3a is generally a high pressure mercury lamp, a halogen lamp, or a xenon lamp, but it can be any other light emitting device such as an electroluminescent diode (LED), a laser, and a discharge lamp without electrode The reflective mirror 3b is formed in an elliptical plane or a parabolic plane, but it can be of any shape and any configuration and is not limited to those described as long as the light can concentrate on the polarization conversion element 5. For example, to make the incident light on an integrating lens 4 approximately parallel to an optical axis C, the reflective mirror 3b should be formed in the shape of a parabola; or if the reflective mirror is in the form of an ellipse, a concave lens should be provided between the light source system 3 and the integrating lens 4 (see Figure 32).

The integrating lens 4 is provided in an optical path between the light source system 3 and the light valve 2 and is configured to make the distribution of light illumination applied from light source system 3 to the light valve 2 Be uniform. The integrating lens 4 includes a first lens array 4a and a second lens array 4b separated from the first lens array 4a. The first lens array 4a and the second lens array 4b are each an array of a plurality of convex lenses. The convex lenses in the first lens array 4a and the convex lenses in the second lens array 4b correspond to each other and are facing each other.

The polarization conversion element 5 converts incident light beams on the polarization conversion element 5 into a single type of linearly polarized light and emits the linearly polarized light. It is provided with an appropriate space in the direction of the x-axis. Figure 2 is a block diagram of the polarization conversion element 5 according to the first preferred embodiment of the invention. As shown in Figure 2, the polarization conversion element 5 includes a plurality of polarization separation films 5a inclined (eg, 45 degrees) towards the direction of the optical axis C (the z direction); a plurality of reflection films 5b arranged between the polarization separation films 5a and inclined (for example, 45 degrees) towards the direction of the optical axis C (the z direction); and phase difference plates N / 2 5c arranged in a plane of the polarization conversion element 5 are applied on the side of the light valve 2 and in positions where the light passes through the polarization separation films 5a. The incident light on the polarization conversion element 5 is separated in the polarized light s and the polarized light p by the polarization separation films 5a. The polarized light p which is transmitted through the polarization separation films 5a, is converted into polarized light s by the phase difference plates N / 2 5c, and is then emitted from the polarization conversion element 5. By On the other hand, the polarized light s is reflected in the polarization separation films 5a and in the reflection films 5b and is then emitted from the polarization conversion element 5. Consequently, the outgoing beams of the polarization conversion element 5 They are almost all polarized light.

The light quantity control system 9 (light quantity control mechanism)) is provided in the optical path and includes a turning mechanism 9a that includes a pair of light shielding bodies that rotate like a double door with the in order to adjust the amount of light applied from the light source system 3 to the light valve 2. The light quantity control system 9 includes the rotation mechanism 9a provided between the first lens matrix 4a and the second matrix of lenses 4b; a signal detector 9b that detects a video signal sent to the light valve 2, and which calculates, based on the detection result, the relative percentage of the amount of light applied to the light valve 2; and a rotation controller 9c that controls the rotation of the rotation mechanism 9a based on the relative percentage of the amount of light calculated by the signal detector 9b. As shown in Figure 3B, the rotation mechanism 9a includes light shielding bodies 9T and 9B that are folded in a V-shape in one direction to reduce the amount of light (block the light). The light shielding bodies 9T and 9B have at their tips cuts 9g that regulate the passage of light. The cuts 9g can be of any shape such as a concave curve, a parabola, a semi-ellipse, and a triangle.

A description of the contrast enhancement is provided below. When a video signal represents 100% of the relative percentage of the amount of light, the control is carried out based on 100% of the relative percentage of the amount of light without light blocking by the turning mechanism 9a. For example, when a video signal represents 20% of the relative percentage of the amount of light, the turning mechanism 9a blocks the light until the relative percentage of the amount of light becomes 20%, so that it is approximately five-fold fine adjustment of the video signal is possible. By reducing the relative percentage of the amount of light by blocking the light using the turning mechanism 9a, a darker black can be obtained compared to the case where a video signal represents 0% of the relative percentage of the amount of light in which Case light blocking is not provided. In other words, since the transmission of the light valve 2 is approximately constant, the reduction of the amount of light applied to the light valve 2 using the rotation mechanism 9a makes it possible to obscure an image projected onto a screen. , thus achieving a contrast enhancement.

Figure 4A shows a 15 degree rotation of the light shielding bodies 9T and 9B of Figure 3A, and Figure 4B shows a 15 degree rotation of the light shielding bodies 9T and 9B of Figure 3B. With reference to the amounts of displacement of the tips of the light shielding bodies 9T and 9B in the z direction, as shown in Figures 4A and 4B, the amount of displacement Zb in Figure 4B is less than the amount of displacement Za in Figure 4A (Za> Zb), from which it can be found that the amount of displacement of the light shielding bodies 9T and 9B in the direction and by angle of rotation is greater in Figure 4B. Accordingly, the light shielding bodies 9T and 9B in the form shown in Figure 4B can provide illumination with 100% of the relative percentage of the amount of light with a lower angle of rotation.

Figure 5 shows the relationship between the angle of rotation and the relative percentage of the amount of light in cases where the rotation mechanism 9a has the shapes of Figures 3A and 3B. The angles VT and VB in Figure 3B will be 20 degrees and the turning mechanism 9a in both Figures 3A and 3B rotates two degrees at the same time. The angle of rotation of 0 degrees refers to the condition that the light shielding bodies 9T and 9B are in completely closed positions, that is, the light shielding bodies 9T and 9B are in the positions indicated by 41a in the Figure 4A and 41b in Figure 4B, respectively. Curve 50 shows the simulation result for the rotation mechanism 9a in the form of Figure 3A, and curve 51 shows the simulation result for the rotation mechanism 9a in the form of Figure 3B. As shown in Figure 5, curve 51 begins to rise before curve 50 with a low relative percentage of the amount of light and reaches 100% of the relative percentage of the amount of light with the angle of rotation of approximately 75 degrees. Due to its narrower range of operating angles, the shape of Figure 3B allows highly responsive control compared to the shape of Figure 3A. It can also be seen from curves 50 and 51 that, except where the relative percentage of the amount of light is low, the rate of change in the relative percentage of the amount of light with respect to the angle of rotation is approximately the same. Of the latter, as will be described later with Figure 14, in the case of a low relative percentage of the amount of light, the irregularity of illumination can be reduced by folding the end portions of the light shielding bodies 9T and 9B V-shaped in the direction of the turning radius. It can also be seen from Figure 5 that the light shielding bodies 9T and 9B each having the two cuts 9g at the tip as shown in Figures 3A and 3B allow a continuous control of the amount of light. While, in this example of the invention, the angles VT and VB are set at 20 degrees, they can be of any degree, and the same effect can be achieved without satisfying VT = VB. The relationship between the rotation angle of the rotation mechanism 9a and the relative percentage of the amount of light in the light valve 2, shown in the example of the invention, is for the case where the input is a signal representing 100 % of the relative percentage of the amount of light, so that the property of the rotation mechanism 9a is represented.

Figures 6A and 6B show the positions of the tips of the light shielding bodies 9T and 9B in the z direction when the relative percentage of the amount of light is 20% in Figure 5. As shown in Figure 6A , the angle of rotation in the case of the shape of Figure 3A is approximately 24 degrees, that is, a1 '24, while the angle of rotation in the case of the shape of Figure 3B is approximately 34 degrees, that is, a2 '34 ,. The angle a3 in Figure 6B is equal to VT and will be 20 degrees. If d1 is the length of the light shielding bodies 9T and 9B of Figure 6A; d2 is the length of the light shielding bodies 9T and 9B of Figure 6B of the axis of rotation at its fold; and d3 is the length of the light shielding bodies 9T and 9B of Figure 6B of their folds to the tips. Based on the conditions described above, the positions of the tips of the light shielding bodies 9T and 9B can be calculated with the shape of Figure 3B in the z direction.

From Figures 6A and 6B, the amounts of displacement Zc and Zd of the light shielding bodies 9T and 9B in the z direction can be expressed with the following equations (1) and (2), respectively.

From Figure 4B, d1 can be expressed with the following expression (3).

In this way, Zc can be expressed with the following equation (4), so that the condition Zc> Zd can be satisfied with equation (5).

Accordingly, by making length d2 shorter than length d3, the shape of Figure 3B can reduce the irregularity of illumination compared to the shape of Figure 3A. Since the displacement distance of the tips of the light shielding bodies 9T and 9B is not the only cause of lighting irregularity, the condition of equation (5) should preferably be satisfied but not a necessity.

Figure 7 shows the distribution of light illumination applied to the light valve 2 when the shape of Figure 3B provides a complete block of light. In the case of complete light blocking, the irregularity of illumination does not occur because the incident light on the second lens array 4b is uniformly superimposed and applied in general lines in its entirety (area 7a) and around both portions of x-direction end (areas 7b) of the light valve 2. Area 7a shows the distribution of light illumination applied from the cells to the light valve 2 (area 30 in Figure 3B) when the opening of the cells in the second lens array 4b is approximately fully open, and areas 7b show the lighting distribution of the light applied from the cells to the light valve 2 (areas 31 in Figure 3B) when the opening of the cells in the second lens array 4b is approximately half open.

Figure 8 shows the relationship between the angle of rotation and the relative percentage of the amount of light in the case where the light shielding bodies 9T and 9B that are not folded have no cuts. The simulation is carried out for every two degrees of the angle of rotation. It can be seen from curve 80 that the rate of change in the relative percentage of the amount of light with respect to the angle of rotation is not continuous, and that the curve has four flat parts (8a, 8b, 8c and 8d).

Figure 9 shows light source images in the vicinity of the second lens array 4b. Figure 9 shows the images with 256 grayscale levels. In Figure 9, reference numerals 91 to 94 designate a dark part between the light source images in the + and direction. The four flat parts 8a, 8b, 8c and 8d in Figure 8 correspond to the four dark parts 91, 92, 93 and 94 between the light source images in Figure 9, which confirms that the dark parts between the images Light source are the result of the influence of the flat parts in Figure 8. Thus, to provide a continuous change in the amount of light, it is necessary to simultaneously block the light both in the dark part and in the light part Between the light source images. Since the light shielding bodies 9T and 9B with the cuts as shown in Figures 3A and 3B allow a continuous change in the amount of light as shown in Figure 5, simultaneous light blocking both in the dark parts As clear as the light source images it is possible to make cuts in the light shielding bodies 9T and 9B.

Figure 10 shows an example of the shape of the light shielding bodies 9T and 9B in which the light shielding bodies 9T and 9B each have a single cut 9g to have symmetry with respect to the optical axis C. When such shape provides a complete light block, approximately uniform light distribution of light is given on the light valve 2.

Figure 11 shows the relationship between the angle of rotation and the relative percentage of the amount of light in the case where the light shielding bodies 9T and 9B have the shape of Figure 10. In Figure 10, the angles VT and VB of the light shielding bodies 9T and 9B will be 20 degrees. Curve 110 shows the simulation result for the turning mechanism 9a in the form of Figure 10. Curve 80 shows the simulation result shown in Figure 8 for the turning mechanism 9a without cuts, for comparison of the effect between the presence and absence of cuts 9g. To facilitate comparison, curve 80 is shifted to coincide with curve 110. It can be seen from Figure 11 that even the light shielding bodies 9T and 9B with only a cut 9g can provide a control of amount of light more continuous than the 9T and 9B light shielding bodies without cuts. In other words, the realization of at least one cut 9g in the light shielding bodies 9T and 9B is effective in achieving a continuous amount of light control. However, it can be seen that of the curve 51 in Figure 5 and of the curve 110 in Figure 11 the light shielding plates 9T and 9B with two cuts produce a smoother change in the amount of light than in those They have only one cut. Therefore, it is more preferable to provide a plurality of cuts for a smoother amount of light control.

Figure 12 shows the light paths when the light shielding bodies 9T and 9B rotate towards the first lens array 4a at the time of light blocking, and especially shows the light paths passing through the cell of lens that is further away in the + direction and in the first lens array 4a. Although only the light shielding body 9T is described herein, the same applies to the light shielding body 9B. Reference number 120a designates the light path that passes through the + side and the center of the lens cell; reference number 120b designates the light path that passes through the center of the lens cell; and reference number 120c designates the path of light passing through the side - and the center of the lens cell. As shown in Figure 12, when the light shielding body 9T is folded forming a small angle or folded in a position that is far from the axis of rotation, unnecessarily the light reflected in the light shielding body 9T passes through of the second lens array 4b and, after multipath reflection inside a housing (not shown) of the optical lighting system 1, may appear on a screen. Therefore, the light shielding bodies 9T and 9B that rotate towards the second lens array 4b at the time of the light blocking are more preferable than the light shielding bodies 9T and 9B that open and close in the direction shown in figure 12.

Figure 13A shows the light paths when the light shielding bodies 9T and 9B are smaller in the x and y direction dimensions to the first lens matrix 4a and the second lens matrix 4b. Figure 13B shows a comparison of the x and y direction dimensions between the light shielding bodies 9T and 9B and the second lens array 4b, from which it can be seen that the light shielding bodies 9T and 9B have dimensions x and direction inferior to the second lens array 4a. Although only the light shielding body 9T is described herein, the same applies to the light shielding body 9B. Reference number 130a designates the light path that passes through the center of the light cell which is the fifth in the + direction and of the optical axis C in the first lens array 4a; and reference number 130b designates the path of light passing through the + x side of the center of the lens cell which is the second in the + y direction and the third in the + x direction of the optical axis C in the first matrix of 4A lenses. It can be seen in Figure 13A that the light passing through these cells that are on the + side and of the axes of rotation of the light shielding bodies 9T and 9B in the first lens array 4a passes through the + side and without entering the light shielding bodies 9T and 9B. Thus, to control the amount of light emitted by the first lens array 4a using the light shielding bodies 9T and 9B, the light shielding bodies 9T and 9B should preferably have x and x direction dimensions greater than the first array. of lenses 4a and the second array of lenses 4b. In the case where the second lens array 4b is larger in size than the first lens array 4a, although it is preferable that the light shielding bodies 9T and 9B have x and x direction dimensions greater than the second lens array 4b, it is it is possible to unnecessarily block the light passing through the second lens matrix 4b by providing a light shielding plate between the second lens matrix 4b and the polarization conversion element 5. Therefore, it can be said that the bodies of Light shielding 9T and 9B are not necessarily superior in the x-directional dimensions and the first lens matrix 4a and the second lens matrix 4b.

Figure 14 shows the light paths calculated by inverse ray tracing from the center of the light valve

2. Reference number 140 designates the light paths; and reference number 141 designates the area where the light paths indicated by 140 are concentrated. Since it can be seen in Figure 14 that an image is formed in the vicinity of the first lens array 4a in the light valve 2, the light valve 2 and the surrounding light surface area of the first light matrix 4th lenses are combined. Thus, when the tips of the light shielding bodies 9T and 9B are in the vicinity of the area 141, the tips of the light shielding bodies 9T and 9B are displayed on the light valve 2, which unnecessarily causes a linear irregularity of illumination in the x-direction in the vicinity of the center in the light valve 2. Therefore, it is preferable that the tips of the light shielding bodies 9T and 9B are brought near the second lens array 4b , that is, the axes of rotation are in the proximity of the second lens array 4b.

Focusing on the tips of the shielding bodies 9T and 9B, since the light shielding bodies 9T and 9B folded in a V-shape in a direction to reduce the amount of light (block the light) are displayed with a narrower width in the direction and that the unfolded light shielding bodies 9T and 9B (cf., dy1 in Figure 15B and dy2 in Figure 16B), can reduce the irregularity of illumination in the light valve 2. Therefore, it can be said that the irregularity of illumination in the light valve 2 can be reduced by folding the light shielding bodies 9T and 9B in the form of a V in one direction to reduce the amount of light (block the light).

Figures 15A and 15B and Figures 16A and 16B show the turning positions of the light shielding bodies 9T and 9B with the shapes of Figures 3A and 3B when the tips of the light shielding bodies 9T and 9B are displayed. in the light valve 2. The condition that an image is formed on the light valve 2 is that the tips of the light shielding bodies 9T and 9B are in proximity to the first lens array 4a and in positions that they are equivalent to the centers of the curvatures of the lens cells which are the second in the + and y -y directions of the optical axis C in the second lens array 4b. Reference numbers 150, 151, 160 and 161 designate the axis passing through the center of the curvature of the lens cell which is the second in the + and or -y direction of the optical axis C in the second lens array 4b; and reference numbers 152 and 162 designate the tip of the light shielding body 9T.

The reason why the tips of the light shielding bodies 9T and 9B should be in positions equivalent to the centers of the curvatures of the lens cells that are second at 7 5 will now be described.

+ and and –y directions of the optical axis C in the second lens array 4b. First, in the positions that are equivalent to the centers of the curvatures of the lens cells that are the first in the + and and -y directions of the optical axis C in the second lens array 4b, it is difficult to verify the irregularity of lighting on the light valve 2 due to the low lighting. In the positions that are equivalent to the centers of the curvatures of the lens cells that are the third in the + and and -y directions of the optical axis in the second lens array 4b, the light with uniformity of illumination is superimposed on the valve of light 2 of the lens cells that are the first in the + yy –y directions of the optical axis C and the lens cells that are the second in the + yy –y directions of the optical axis C, which relatively reduces the lighting irregularity in the light valve 2 and in this way it is difficult to verify the lighting irregularity caused by the lens cells which are the third in the + yy –y directions of the optical axis

C. Consequently, as a condition that allows the ease of verifying the display of the points of the light shielding bodies 9T and 9B on the light valve 2, the tips of the light shielding bodies 9T and 9B should be in the positions equivalent to the centers of the curvatures of the lens cells that are the second in the + and y -y directions of the optical axis C in the second lens matrix 4b.

Figure 17A shows the simulation result of the lighting distribution on the light valve 2 when the light shielding bodies 9T and 9B do not have such a cut 9g as shown in Figure 3A and are in the condition of Figures 15A and 15B; and Figure 17B shows the simulation result of the lighting distribution on the light valve 2 when the light shielding bodies 9T and 9B do not have such a cut 9g as shown in Figure 3B and are in the condition of the figures 16A and 16B. In Figures 17A and 17B, reference numbers 170a and 170b designate the area with low illumination; and reference numbers 171a and 171b designate the axis and passing through the center of the light valve 2. The comparison of areas 170a and 170b shows that area 170b has a uniformity of illumination greater than area 170a. This is due to the presence of the inequality relation dy1> dy2 between the width dy1 of Figure 15B and the width dy2 of Figure 16B. Consequently, the irregularity of illumination on the light valve 2 can be reduced by folding the light shielding bodies 9T and 9B in a V-direction in a direction to reduce the amount of light (block the light). Thus, it can be said that, without satisfying the equation condition (5) mentioned above, the light shielding bodies 9T and 9B with folds can reduce the irregularity of illumination.

Figure 18 shows the simulation result of the lighting distribution on the light valve 2 when the light shielding bodies 9T and 9B are in the form of Figure 3B and in the condition of Figures 16A and 16B. As shown in Figure 18, there is a small area with low illumination in the x direction from the center of the light valve 2. Reference number 180 designates the area with low illumination in the direction and extending from the center of the light valve 2; and reference number 181 designates the axis and passing through the center of the light valve 2. Although there is only a slight irregularity of illumination in the area 180 because of the cuts 9g in the light shielding bodies 9T and 9B which form the light collection sites in the second lens array 4b, is not a problem because the entire lighting distribution of the light valve 2 is approximately uniform. Consequently, the superposition of the tips displayed on the light valve 2 can be reduced by folding the light shielding bodies 9T and 9B in a V-direction in a direction to reduce the amount of light (block the light); forming at least one cut in the tips of the light shielding bodies 9T and 9B; and also reducing flat parts of the tips other than the cuts. This results in a considerable reduction in lighting irregularity.

Figure 19 shows the relative percentage of the amount of light in the direction and on the axes and 171a, 171b, and 181 shown in Figures 17A and 17B and Figure 18, respectively. The horizontal axis corresponds to the vertical axis on the valve 2 shown in Figure 18. In Figure 19, reference number 190 designates the relative percentage of the amount of light on the axis and 171a; reference number 191 designates the relative percentage of the amount of light on the axis and 171b; and reference number 192 designates the relative percentage of the amount of light on the axis and 181. With reference to Figure 19, the comparison of the values of the relative percentage of the amount of light at 0.50Y, which is the center of direction and of the light valve 2, produces the inequality 190 <191 <192 and shows that the irregularity of illumination is reduced in the order of 190, 191 and 192. This indicates that the irregularity of illumination can be reduced by forming the bodies 9T and 9B light shielding with V-shaped folds in one direction to reduce the amount of light (block the light) and with sharp cuts.

While this example has described the case where VT = a2 = a3 in Figure 6B when the light shielding bodies 9T and 9B are in the position 41b shown in Figure 4B, the width dy2 in Figure 16B can also be reduce in the case where a3> a2 = VT, in which case the lighting irregularity can be reduced more than in the case of the shape of Figure 4B. In addition, while the light shielding bodies 9T and 9B each have only one fold, they can have two folds if the width dy2 in Figure 16B can be reduced further. By doing so, the irregularity of lighting can be further reduced. While the light shielding bodies 9T and 9B in Figure 3B fold in the proximity of the lens cell which is the second in the direction and of the optical axis C as the center in the second lens array 4b, these can be folded in any position.

From the above description, it is evident that the continuous control of amount of light without causing irregularity of illumination on the light valve 2 can be carried out by forming the light shielding bodies 9T and 9B in the rotation mechanism 9a with a fold V-shaped in one direction to reduce the amount of light (block the light) and with at least one cut at its tips.

‘Preferred realization’

Figure 20 is a block diagram of an optical lighting system 1b in a projection display according to a preferred embodiment of the invention. The preferred embodiment of the invention is characterized in that the light shielding bodies 9T and 9B in the rotation mechanism 9a have a sharp edge tip. The other parts of the configuration and operation are identical to those described in the first example and thus are not described herein.

Figures 21A and 21B are the same drawings as Figures 15A and 15B; and Figures 22A and 22B are similar to Figures 15A and 15B in the positions of the light shielding bodies 9T and 9B. Reference numbers 210, 211, 220 and 221 designate the axis that passes through the center of the curvature of a lens cell which is the second in the + and y –y direction of the optical axis C in the second lens matrix 4b. As shown in Figures 22A and 22B, the light shielding bodies 9T and 9B on the optical axis side C of the axis 220 have a sharp edge tip. By doing so, the widths of the tips are reduced by dy. The width t of the light shielding bodies 9T and 9B is generally about 0.5 mm considering the intensity of the light shielding bodies 9T and 9B with respect to the rotation of the rotation mechanism 9a. Reference numbers 212 and 222 designate the tip of the light shielding body 9T.

Figure 23A shows the simulation result of the lighting distribution on the light valve 2 when the light shielding bodies 9T and 9B do not have such a cut 9g as shown in Figure 3A and are in the condition of Figures 21A and 21B; and Figure 23B shows the simulation result of the lighting distribution on the light valve 2 when the light shielding bodies 9T and 9B do not have such a cut 9g as shown in Figure 3A and are in the condition of the figures 22A and 22B. It is assumed that t = 0.55 mm. In Figures 23A and 23B, reference numbers 230 and 230b designate the area with low illumination; and reference numbers 231a and 231b designate the axis and passing through the center of the light valve 2. The comparison of areas 230a and 230b shows that the lighting irregularity in area 230b is considerably improved. Consequently, as shown in Figures 22A and 22B, the irregularity of illumination can be considerably reduced by sharply sharpening the tips of the light shielding bodies 9T and 9B on the optical axis side C of the axes passing through the centers of the curvatures of the lens cells that are second in the + and y -y directions of the optical axis C in the second lens array 4b.

Figure 24 shows the relative percentage of the amount of light in the direction and on the axes and 231a and 231b shown in Figures 23 and 23B, respectively. In Figure 24, reference number 240 designates the relative percentage of the amount of light on the axis and 231a; and reference number 241 designates the relative percentage of the amount of light on the y-axis 231b. With reference to Figure 24, the comparison of the values of the relative percentage of the amount of light in 0.05Y, which is the center of direction and of the light valve 2, shows that the relative percentage indicated by 241 is greater than relative percentage indicated by 240, that is, the lighting irregularity is greatly reduced. This indicates that the irregularity of illumination can be considerably reduced by sharply sharpening the tips of the light shielding bodies 9T and 9B on the optical axis side C of the axes that pass through the centers of the curvatures of the lens cells which are the second in the + and yy directions of the optical axis C in the second lens array 4b.

Figures 25A and 25B show the shape of the tips of the light shielding bodies 9T and 9B. Reference numbers 250 and 251 designate the axes that pass through the center of the curvature of a lens cell which are the seconds in the + and y –y direction of the optical axis C in the second lens array 4b. It can be seen in Figures 25A and 25B that the angles at the tips of the light shielding bodies 9T and 9B should preferably be less than f

From the above description, it is evident that continuous control of the amount of light can be carried out without causing irregularity of illumination on the light valve 2 forming at least a cut in the tips of the light shielding bodies 9T and 9B and in addition, sharply sharpening the tips of the light shielding bodies 9T and 9B.

‘Additional preferred embodiment’

Figure 26 is a block diagram of an optical lighting system 1c in a projection display according to a further preferred embodiment of the invention. The further preferred embodiment of the invention is characterized in that the light shielding bodies 9T and 9B with small opening areas at their tips can perform sufficiently high contrast without causing irregularity of illumination on the light valve 2. The other parts of the configuration and operation are identical to those described in the first example and thus are not described in this document.

The light 270 emitted by the second lens array 4b is incident on the light valve 2 with a greater degree of incident. At this time, since the contrast is reduced by increasing the incident angle of light on the light valve 2 due to the property of the light valves (see Figure 29), the light shielding bodies 9T and 9B should preferably be configured to block the incident light with greater incident angles on the light valve 2, that is to block the incident light in the x direction.

Figure 28A shows an example of the x plane, and of the second lens array 4b and the polarization conversion element 5, in which the part on the right (a) shows a front view and the part on the left (b ) shows a side view. Figure 28B shows a detailed representation of Figure 2. Also, Figure 28B shows the incident light path on the second lens array 4b. The dotted lines part shows the polarization conversion element 5, and the shaded parts show the phase difference plates N / 2 5c. In general, polarization conversion is carried out efficiently by concentrating light only on the areas of the phase difference plates N / 2 5c. Thus, light beams 270, 271, 272, 273, 274, and 275 are beams of light converted by polarization. Referring to Figure 28B, outside the linearly polarized incident light p and the polarized light p incident on the polarization conversion element 5 is converted to polarized light s by the phase difference plates N / 2 5c and thus is emitted from the x direction position of the polarization conversion element 5 which is equivalent to the incident position; however, it is emitted at the position that is a distance dx (the distance between 275a and 275b) away from the optical axis C compared to the polarized light s. Therefore, blocking the incident light on the x direction side of the optical axis C becomes essential for contrast enhancement. That is, the beams of light 270 and 275 have an influence on the contrast. In other words, the application of light beams to positions that are close to the optical axis C in the x direction is the condition for contrast enhancement.

Figure 30 shows the shapes of the light shielding bodies 9T and 9B. The light shielding bodies 9T and 9B have two cuts 9g and 9h with different areas at their tips. The 9g cuts have a smaller opening area than the 9h cuts. The cuts 9g and 9h are made in the light shielding bodies 9T and 9B to have points of symmetry with respect to a point in the optical axis c when the light shielding bodies 9T and 9B are approximate.

Figure 31 shows numerically the amount of light that passes through each cell in the second lens array 4b, said amount is calculated by simulation. The shapes of the light shielding bodies 9T and 9B as shown in Figure 30 can reduce a contrast difference in the x direction. Figure 31 shows representatively the upper right quadrant of the second lens matrix 4b since the second lens matrix 4b shows a symmetry both between the upper and lower halves and between the right and left halves.

Figure 32 shows the simulation result for the case where the light emitted by the light source 3a is reflected in the reflecting mirror 3b. The reflective mirror 3b will have the shape of an ellipse, and the light emitted by the light source system 3 will be made parallel by a concave lens 310. In general, there is a light source valve in the vicinity of the optical axis C , and reference number 311 designates an opening of such a valve.

Since the opening 311 is in such shape as shown in Figure 2, the cell that is in the fourth column V1 and the fifth row H1 (V1H1) of the second lens array 4b shown in Figure 31 receives only a small amount of light emitted by the light source system 3. When the light shielding bodies 9T and 9B in the form of Figure 30 provide a complete blockage of the light, the cuts 9g radiate both end portions of the valve light in the x direction, and the cuts 9h radiate a central portion of the light valve 2. Therefore, a uniform illumination distribution can be obtained by matching and superimposing the relative amounts of light applied to both end portions in the direction x and the central portion of the light valve 2. For example when the cuts 9g and 9h have the same shape, as shown in Figure 33, the irregularity of lighting occurs due to the low illumination in the portion n center of the light valve 2. Thus, the cuts 9h need to have an opening area greater than the cuts 9h. with reference to FIG. 33, the light emitted by the cuts 9g radiates an area 32b on the light valve 2, and the light emitted by the cuts 9g radiates an area 32a on the light valve 2.

Figure 34 shows the shapes of the light shielding bodies 9T and 9B that are determined in consideration of the contrast. A cut 9i is made in the cell (V1H1) to form an opening in the form of a right triangle, so that a uniform illumination distribution is provided on the light valve 2. However, Figure 31 shows that only a small amount of light passes through the cell (V1H1). Thus, in the case where a 100% video signal is displayed on the screen, the contrast of an image projected on the screen is unsatisfactory due to a small amount of light.

Of the foregoing, in general, to prevent irregularity of illumination on the light valve 2, approximately eight cells are required as an opening. However, considering the relative shape and percentage of the amount of light incident on the opening, the uniformity of illumination on the light valve can be achieved with approximately four cells. Specifically, the vertex of each of the cuts 9h with a greater opening area in the x-direction is made equivalent to the center of the x-direction of the cell (in the fourth column V1 and the fifth row H1) that is closest of the optical axis C, and the vertex of each of the cuts 9g with a smaller opening area is made equivalent to a junction between the cell (in the fourth column V1 and the fifth row H1) that is closer to the axis optical C and the adjacent cell (in the fifth column V2 and the fifth row H1) on the opposite side of the optical axis

C. By doing so, a contrast enhancement can be achieved with approximately four cells, without causing irregularity of illumination in the light valve 2.

Figure 35 shows the relationship between the angle of rotation and the relative percentage of the amount of light in the case where the light shielding bodies 9T and 9B have the shape of Figure 30. Curve 331 shows the simulation result for the turning mechanism 9a with the shape of figure 30, and the curve 330 shows the simulation result of figure 8 for the turning mechanism 9a without cuts. To facilitate the comparison, the curve 330 is shifted to coincide with the curve 331. It can be seen in Figure 35 that the light shielding bodies 9T and 9B with the shape shown in Figure 30 provide almost quantity control of light continuous on the light valve (2) with respect to the angle of rotation. Consequently, it can be said that the light shielding bodies 9T and 9B with the tips as shown in Figure 30 can achieve continuous light quantity control without causing irregularity

5 of illumination in the light valve 2, thereby improving the contrast.

Although this preferred embodiment illustrates an example of the cuts in the form of an ellipse, the same effect can be achieved with cuts in the form of a triangle as long as the same consideration is described as described in this preferred embodiment in the opening area and the positions of the vertices.

Figure 36 shows the shapes of the light shielding bodies 9T and 9B. Light shielding bodies

10 9T and 9B have triangular cuts at their tips. The shape of Figure 36 allows a fine control of the amount of light when the relative percentage of the amount of light is 30% or less. Providing the cuts 9g envelopes on both sides of the second lens array in the x direction allows fine control of a portion with a low relative percentage of the amount of light. Although only a small number of cells in the second lens array 4b are used for complete light blocking, the triangular shape as shown in Figure 36 provides a lighting distribution

15 uniformly over the light valve 2 superimposing the irradiated areas, thus preventing irregularity of lighting.

Figure 37 shows the relationship between the angle of rotation and the relative percentage of the amount of light in the case where the light shielding bodies 9T and 9B have the shape of Figure 36. Curve 351 shows the simulation result with the shape shown in Figure 38. To facilitate comparison, curve 350 is shifted to coincide with curve 351. It can be seen in Figure 37 that, in the case of the light shielding bodies 9T and 9B of the In the form of Figure 36, the curve has a smooth inclination of approximately 10% to 30%. The reason for such a smooth curve is that, in the case of a small angle of rotation of the rotation mechanism 9a, the blocking of light in the lens cell in the fourth column V1 and the fifth row H1 shown in Figure 31 reduces the lighting change rate. In the interval with a low relative percentage of the amount of light, specifically between 10% and 30%, the sensitivity of the eye

The change in the relative percentage of the amount of light is especially high, so that fine control of the amount of light using the turning mechanism 9a becomes important. The shape shown in Figure 36 allows fine control of the amount of light when the relative percentage of the amount of light is 30% or less.

From the above description, the light shielding bodies 9T and 9B with the shape shown in Figure 36 allow a fine control of the amount of light with a low relative percentage of the amount of light.

Claims (12)

1.-A projection display comprising: a light valve (2); a light source (3a) that generates light applied to said light valve (2); an integrating lens (4) provided on an optical path with an optical axis between said light source (3a) and said lens valve (2) and which unifies a distribution of light illumination applied from said light source (3a) to said light valve (2); and a mechanism (9) for controlling the amount of light provided in said optical path and including a pair of light shielding bodies (9B, 9T) arranged on opposite sides of the optical axis c, each light shielding body being ( 9B, 9T) rotatably arranged around an axis of rotation to thereby adjust the amount of light passing from said light source (3a) to said light valve (2), the rotation axes being arranged parallel between yes and orthogonal to the optical axis c, in which each of said light shielding bodies is shaped like a plate, and in which the thickness of said light shielding bodies (9B, 9T) is reduced at their tips for that in this way the light shielding bodies (9B, 9T) have sharp edge tips on their side of the optical axis. 2. The projection display according to claim 1, wherein said light shielding bodies (9B, 9T) have a cut in their tips. 3. The projection display according to claim 1, in which said integrating lens (4) includes a first array of lenses (4a) provided on the side of said light source (3a), and a second array of lenses (4b) provided on the side of said light valve (2) and said light shielding bodies (9B, 9T) are provided between said first lens matrix (4a) and said second lens matrix (4b), and rotate in a direction to open towards and close from said first lens matrix (4a ). 4. The projection display according to claim 3, wherein the axes of rotation of said light shielding bodies (9B, 9T) are between said first lens matrix (4a) and said second lens matrix (4b) and the axes of rotation of the light shielding bodies they are closer to the second lens matrix than to the first lens matrix. 5. The projection display according to claim 1, wherein said pair of light shielding bodies (9B, 9T) have a larger dimension in a direction of the turning radius than said integrating lens (4). 6. The projection display according to claim 2, in which said cut is made in the form of a concave curve. 7. The projection display according to claim 2, in which said cut is made in the form of a parabola. 8. The projection display according to claim 2, in which said cut is made in the form of a semi-ellipse. 9. The projection display according to claim 2, in which said cut is made in the form of a triangle. 10. The projection display according to claim 1, wherein said light shielding bodies (9B, 9T) have a plurality of cuts at their tips. 11. The projection display according to claim 3, wherein said light shielding bodies (9B, 9T) respectively have two cuts that have different areas and are made in said light shielding bodies (9B, 9T) to have a point of symmetry with respect to a point on an axis optical when said light shielding bodies (9B, 9T) are closed. 12. The projection display according to claim 11, wherein in an x, y, z coordinate system in which the z axis is an address of said optical axis, the x axis is a lateral direction orthogonal to said axis z, and the y axis is a vertical direction orthogonal to said z axis and said x axis, said two cuts with different areas are such that when the light shielding bodies (9B, 9T) are closed: one of said two cuts of one of said light shielding bodies having an opening area 5 has a vertex that is in the axis direction and next to the center of a lens cell of said second lens array, said lens cell being closer to said optical axis, and one of said two cuts of the other of said light shielding bodies having a smaller opening area has a vertex that is in the axis direction and next to a joint between said lens cell and another lens cell that is on the x-axis and that is adjacent to said lens cell on the side of said lens cell 10 opposite said optical axis.