JPS58187918A - Transmission type video screen - Google Patents

Abstract

PURPOSE:To obtain a video having an extremely high quality, by deflecting the left and right image beams to the optical axis side by the first lens face for improving the directivity of a screen, and the second lens face provided in the vicinity of its focal face. CONSTITUTION:A transmission screen 7 is constituted of a Fresnel lens 8 and a lens 9 provided with a semi-cylindrical lens face (lenticular) having a lot of longitudinal lines on the face opposed to said lens. In this case, a correcting lens face 9b is formed in the vicinity of a focal face of a semi-cylindrical lens face 9a, so that image beams of both sides of the center optical axis are deflected to an optical axis Z as shown by a one point chain line in the figure. In this way, a dispersion characteristic is obtained by the first lens face 9a, a monitoring area angle is secured, also uneven luminance, a color shift, etc. can be corrected by the second lens face 9b, and a video having an extremely high quality can be obtained.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention provides a transmission-type image display device for an image display device in which a 1ψ light source is arranged behind a screen through a lens system, and the image 1ψ projected onto the screen is viewed from the front side of the screen. Regarding the screen.

FIG. 1 is a diagram showing the conventionally well-known principle of such a video display device (for example, a video projector).

This display device uses at least two image light sources (for example, a three-color R, G%B CRT (1112) t3+) and a lens system (41 (Fit (61) to transmit image rays from a transmissive screen (7). Project from behind the screen (7
) is configured so that the enlarged image is viewed from the front side.

FIG. 2 is a partial optical path diagram of the projector shown in FIG. 1. For example, the image of OR,T(1) is
An image is formed on a screen (7) by a projection lens system (4) having a principal point H' near the focal point of the Fresnel lens constituting the image plane. In order to ensure a viewable angle range on the front side of the screen (7), the pixel P of the screen (7)
The divergence angle ψ of 0° to 20° in the vertical direction and 0° to 20° in the horizontal direction
It needs to be at about 90°.

For this reason, conventionally, a screen structure shown in a partial perspective view of FIG. 3 or 4 has been adopted. In FIGS. 6 and 4, the screen (7) is constructed with a Fresnel lens (8) and a semi-cylindrical lens (9) (wrench killer) provided on the front side thereof.

A large number of semi-cylindrical lenses (9) are arranged in a column, thereby providing horizontal divergence characteristics (brightness directional characteristics).

Also, for vertical divergence I, a semi-cylindrical lens (9)
A diffusing agent is mixed in to give the necessary brightness directional characteristics.

In the screen shown in FIG. 95, there is also known a screen in which a lens surface is further formed on the cylindrical lens surface to obtain a vertical divergence characteristic.

5 is a partial horizontal sectional view showing the optical path of the image ray passing through the screen (7) in FIG. 4, and FIG. 6 is an enlarged sectional view of the lens (91) in FIG. The effect of the screen (7) consisting of the Fresnel lens (8) and the semi-cylindrical lens (9) in Fig. 4 as a wrench killer is as shown in the optical path of Fig. 5. That is, the Fresnel lens (8)
The principal light mL1 of the light beam from the projection lens system (5), which has a principal point near the focal point of , is almost parallel to the Fresnel lens surface, so the lenticular surface E' on the front side of the screen is
As shown in FIG. 5, it is symmetrical with respect to the optical axis.

On the other hand, for the projection lens system (41 (61) shown in Figure 1lE1, which is not on the optical axis of the Fresnel lens,
Principal light III of the luminous flux as shown by the dotted line in the figure! The lenticular surface E' is asymmetrical with respect to the L circle. For this reason, in a projector equipped with a plurality of projection lens systems (41 (51 (61)), the image on the screen (7) is uneven in brightness, color shading (phase shift depending on the location on the screen), color shift ( color shift) may occur.

The present invention provides a transparent screen that overcomes the above-mentioned problems.

Embodiments of the present invention will be described below based on the drawings.

FIG. 7 is a partial perspective view showing the structure of a transparent screen (7) according to the invention. This screen (7) is
As shown in Fig. 11113, a Fresnel lens (8) and a lens (9) equipped with a large number of longitudinal semi-cylindrical lens surfaces (wrench killers) on the surface facing the Fresnel lens (8) are shown.
). The semi-cylindrical lens surface (9a) of the lens (9) has a reflection angle of each semi-cylindrical lens i.
II corresponding to lJ! A striped lens surface (9b) (convex lens) is formed.

8A to 8C are partially enlarged views of the horizontal 1lfr leap map of the lens (9!), and A is a projection lens (9!) located on the optical axis.
5) shows a state in which the light beam from point Q converges, if aberrations are ignored. Further, FIG. 8B shows how a light beam whose concentration angle is θ with respect to the optical axis converges at a point Q. Therefore, as shown in Figure 1, there are three projection light sources (
When equipped with a CRT of R1G%B), as shown in FIG.
On one virtual plane S at a distance T from the peak of the semi-cylindrical lens surface (9a), the luminous flux from each light source is separated into six regions R%G and H.

Area P of each segment of the lenticule lens surface (9a)
By forming a thousand horizontal virtual planes of the light beam from each CRT (11121131), uneven brightness, color shift, and color shading can be corrected. Regarding the symmetrical front gate or convex lens surfaces, regions B and R, six vertical lens surfaces are formed of concave or convex lens surfaces whose curvature decreases in the direction away from the optical axis Z and shifts the emitted light rays further toward the optical axis. 0, but the width of such a lens surface is P
/ 5 > 0.5 wa, making manufacturing difficult.

Therefore, in this embodiment, as shown in FIG. ) is formed. On this virtual plane S', as shown in the partially enlarged view of FIG.
, are other convergence points Q2Q5 (B-CRT!31 and R,
-0RT (where 11 is used as a light source) has less aberration, and is almost at one point. On the other hand, another convergence point Q2
At Qs, the light beam is spread out as shown by the dotted line in FIG. 9 due to aberration.

Therefore, in the virtual plane S', FIGS. 7, 8C, and 9
A convex lens surface (9b) symmetrical about the optical axis Z as shown in the figure
), the light beam from the central ORT i2) will not be biased in the horizontal direction (lateral direction), and the C
R,1' (II The luminous flux from 13+ is biased towards the optical axis Z side as shown by the dashed line in FIG. 9, for example. As a result, the directivity in the horizontal direction is improved by the semi-cylindrical lens surface (9a) is done, and brightness unevenness, color shading, and
Color shift is corrected by the convex lens surface (9b). That is, according to the above configuration, the semi-cylindrical lens surface (
9a) gives the necessary divergence characteristics, secures the tax collection area angle on the screen surface side, and corrects the deviation of the light rays of each image light source caused by providing this semi-cylindrical lens surface (9m). (9b), so uneven brightness, color shift, and color shading are improved.In addition, in the conventional gloziector, the concentration angle θ of the optical axis of each image light source shown in Figure 1 is minimized to reduce color shift. However, in this example, since color shift etc. are corrected, the concentration angle θ may be increased, and the degree of freedom in the arrangement of the image light source (11 (21131) is reduced. increase,
It is possible to downsize the device.

Furthermore, C in the center! Since there is no need to correct the luminous flux of RTf21.4, as shown in the modified example in Fig. 10,
In the vicinity of the convergence point Q, the correction lens surface (9b) may be a plane. Further, in the vicinity of other convergence points Q and 2Q of the light beams, it may be inclined at a predetermined angle with respect to the Z axis or may be a flat surface. In this case, since the correction lens surface (9b) is provided near the focal plane of the lens surface (9a) of the wrench killer, the horizontal area of the lens surface (9b) is the pitch of the wrench killer lens surface (9a). P may also be narrow, so the opening of the adjacent lens surface (9b) may be a non-lens surface, and a light absorption layer circle may be provided on this non-lens surface. This light absorption layer 021 alleviates the reduction in image contrast due to disturbance light being diverged on the lens surface.

In addition, based on the same idea, the convex lens surface (9b) may be configured with a concave lens surface.

In the above embodiment, the virtual plane S' on which the correction lens surface (9b) is provided is the semi-cylindrical lens surface (9a) of the wrench killer.
), but its vicinity (Fig. 8C) is preferable.
(between T' and T).

As described above, the transmissive screen according to the present invention scatters the projection light from at least two image light sources (CRT (11+21+31) in the arrangement direction (horizontal direction in the embodiment) of these image light sources to determine the directional characteristics of the screen. A first lens surface (semi-cylindrical lens surface (9a)) to be improved, and a lens t7 provided near the focal plane of this first lens surface, convert the projected light from each image light source into the center light of the first lens surface. It is composed of an axis (a second lens surface that deflects toward the n side).

Therefore, according to the present invention, it is possible to obtain the required dispersion (divergence) property with the first lens surface (semi-cylindrical lens surface) and secure the tax collection area angle, and also to prevent uneven brightness with the second lens surface. , color shift, etc. can be corrected, and extremely high-quality images can be obtained. In addition, since the second lens surface is formed near the focal plane of the first lens surface, the second lens surface only needs to substantially correct a point or a very narrow area of light beam, and the second lens surface 0 has a simple shape and is easy to manufacture.

[Brief explanation of the drawing]

Fig. 1 is a principle diagram of a conventionally well-known video projector using a transparent screen, fs2 is a partial optical path diagram of the video projector shown in Fig. 1, and Figs. FIG. 5 is a partial horizontal cross-sectional view of the screen showing the optical path of the image ray through the screen of FIG. 4; FIG. FIG. 3 is an enlarged cross-sectional view of the lens. FIG. 7 is a partially cutaway perspective view of a transparent screen showing an embodiment of the present invention, and FIG. 8 A-0 is an optical path diagram showing a state of convergence of light beams by the semi-cylindrical lens surface of FIG. 7, respectively. 9th
The figure is an enlarged horizontal sectional view showing the shape of the convex lens surface in Figure 7.
FIG. 10 is a horizontal sectional view showing a modification of the concave lens surface of FIG. 9. FIG. In addition, in the code used in the drawing, (IX2X31------ORT(4f5f6
)・・・・・・・・・ Lens system (71・・・・・・・
・・・・・・・・・ Screen (8)・・・・・・・・・
・－・・・・・・ Fresnel lens (9)・・・・・・
...... Semi-cylindrical lens (9a)...
...... Semi-cylindrical lens surface (9b)...
・・・・・・・・・・・・It is a convex lens surface. Agent Masaru Ueya Yoshio Tsune Toshiki Sugiura Figure 1, Figure 112, Figure 5, Figure 61! i

Claims (1)

[Claims] In a transmission type video screen of a video display device, in which at least two image light sources are arranged behind the screen via a lens system, and the video projected onto the screen is viewed from the front side, the screen has at least two image light sources.
a first lens surface for scattering the projection light from the two image light sources in the arrangement direction of the image light sources to improve the directivity of the screen; and a first lens surface provided near the focal plane of the first lens surface. , and a second lens surface that deflects the projection light from each image light source toward the central optical axis side of the first lens surface.