This invention relates generally to the field of display devices, and more particularly to a curved light guide screen for use in rear projection display devices.
Socially and professionally, most people rely upon video displays in one form or another for at least a portion of their work and/or recreation. With a growing demand for large screens, such as high definition television (HDTV), cathode ray tubes (CRTs) have largely given way to displays composed of liquid crystal devices (LCDs), plasma display panels (PDPs), or front or rear projection systems.
A CRT operates by scanning electron beam(s) that excite phosphor materials on the back side of a transparent screen, wherein the intensity of each pixel is commonly tied to the intensity of the electron beam. With a PDP, each pixel is an individual light-emitting device capable of generating its own light. With an LCD, each pixel is a back-lit, light modulating liquid crystal device.
As neither system utilizes a large tube, LCD and PDP screens may be quite thin and often are lighter than comparable CRT displays. However, the manufacturing process for LCDs, PDPs and most other flat panel displays is much more complex and intensive with respect to both equipment and materials than that of CRTs, typically resulting in higher selling prices.
Projection systems offer alternatives to PDP and LCD based systems. In many cases, projection display systems are less expensive than comparably sized PDP or LCD display systems. Rear projection display systems typically employ a wide angle projection lens (or multiple lenses), operating in connection with one or more reflective surfaces to direct light received from the projector through the lens(es) to the back of a screen. The lens and mirror arrangement typically enlarges the image as well.
To accommodate the projector, one or more lenses, and reflectors, rear projection displays are typically 18 to 20 inches deep and not suitable for on-wall mounting. A typical rear projection system offering a 55-inch HDTV screen may weigh less than a comparable CRT, but at 200+ pounds it may be difficult and awkward to install and support.
Often, rear projection display devices exhibit average or below average picture quality in certain environments. For example, rear projection displays may be difficult to see when viewed from particular angles within a room setting or when light varies within the environment. Aside from a theatrical setting, light output and contrast is a constant issue in most settings and viewing environments. The negative aspects of viewing angle and light variation may be amplified by the flat or planar geometry of current rear projection displays.
A display may also have to contend with two types of contrast—dark room contrast and light room contrast. Dark room contrast is simply the contrast between light and dark image objects in a dark environment such as a theater setting. Light room contrast is simply the contrast between light and dark image objects in a light environment. Front projection systems typically provide good dark room contrast where ambient light is minimized but, as they rely on a screen reflector, they are subject to poor light room contrast due to the interference of ambient light.
Rear projection displays, LEDs, LCDs and PDPs typically provide better light room contrast than front projection systems. However, ambient light striking the viewing surface can be an issue for viewers and buying consumers. Ambient light is oftentimes highly variable. For typical consumers, what makes a display attractive is often high contrast in a bright room. High contrast is difficult to achieve when ambient light strikes the viewing surface at specular or near-specular angles, as is common with flat panel displays.
A developing variation of rear projection displays utilizes light guides, such as optical fibers, to route an image from an input location to an output location and to magnify the image. Such displays may be referred to as light guide screens (LGS's). Light room contrast and dark room contrast are generally issues that also apply to LGS systems.
The light guides, commonly glass or acrylic, are typically manufactured as individual fibers or layers of fibers. The light guide fibers are flexible, and may be bent to accommodate design and manufacturing specifications. Further, precise positioning of each light guide is possible, and often required, to ensure optimal image quality.
Weight, thickness, durability, cost, aesthetic appearance and quality are key considerations for rear projection display systems and display screens. From the manufacturing point of view, cost of production and increased yield are also important.
Hence, there is a need for a rear projection display that overcomes one or more of the drawbacks identified above.
This invention provides a curved screen for light guide screen displays.
In particular, and by way of example only, according to an embodiment of the present invention, provided is a curved light guide screen including: a plurality of magnifying layers, each magnifying layer including a plurality of light guides, and each light guide having an input end, a midsection and a magnifying output end; and a plurality of spacers disposed between two or more magnifying layers to position the layers and define a substantially curvilinear viewing surface.
Before proceeding with the detailed description, it is to be appreciated that the present teaching is by way of example, not by limitation. The concepts herein are not limited to use or application with a specific curved light guide screen. Thus, although the instrumentalities described herein are for the convenience of explanation, shown and described with respect to exemplary embodiments, it will be appreciated that the principles herein may be equally applied in other types of curved light guide screen display systems.
Referring now to the drawings, and more specifically to
As shown in
In enlarged section 113, bounded by dotted line 114, of curvilinear viewing surface 104, the position, shape and orientation of a collection of light guide magnifying output ends may be more fully appreciated. Specifically, in at least one embodiment, the column of exemplary magnifying output ends 116-120, and their corresponding linearly aligned light guides above and below constitute a single light guide magnifying layer 122. In at least one embodiment, curved light guide screen 100 is an assembly of light guide magnifying layers, e.g. magnifying layers 122, 124 and 126, positioned and spaced adjacent one another as discussed in greater detail below.
As shown in enlarged section 114, in at least one embodiment, the magnifying output ends 116, 118, 120 of exemplary magnifying layer 122 are in substantially contiguous parallel contact, without intervening spacers or material separating each individual output end from it's neighbors above and below. In other words, the output ends lie adjacent one another and are in actual contact, touching along their outer surfaces at one or more points. It is of course understood and appreciated that the core (see
Cross-referencing for a moment
Total internal reflection, or TIR, is the reflection of all incident light off a boundary between core 206 and clad 210. TIR occurs when a light ray is both in a medium of higher index of refraction and approaches a medium of lower index of refraction, and the angle of incidence for the light ray is greater than the “critical angle.”
The critical angle is defined as the smallest angle of incidence measured with respect to a line normal to the boundary between two optical media for which light is refracted at an exit angle of 90 degrees (that is, the light propagates along the boundary) when the light impinges on the boundary from the side of the higher index of refraction. For any angle of incidence greater than the critical angle, the light traveling through the medium with a higher index of refraction will undergo total internal reflection. The value of the critical angle depends upon the combination of materials present on each side of the boundary.
In at least one embodiment, for each light guide 200, a substantially circular cross-section input end 202 transitions to a substantially elliptical cross-section, magnifying output end 204. The interior diameter “d1” of input end 202 is not as great as the major axis “l1” of magnifying output end 204. Moreover, the magnification property of magnifying output end 204 is provided in at least one embodiment by configuring magnifying output end 204 at an acute angle “θ1” relative to longitudinal centerline 208 of light guide 200.
In at least one alternative embodiment, light guide 200 may have input and magnifying output end cross-sections relating to a square, triangle, trapezoid, octagon or other polygon. In addition, in at least one embodiment, the midsection 205 is a flexible midsection. As such, it is understood and appreciated that light guide 200 may bend and twist such that longitudinal centerline 208 is not always a straight line.
As shown in
As shown, the magnifying output ends 312, 314 and 316, of light guides 300, 302 and 304 respectively, are oriented at an acute angle “θ2” relative to a centerline 318 of light guide 300. Collectively, magnifying output ends, e.g. ends 312-316, form viewing surface 104.
The input ends of all light guides, e.g. light guides 300-304, are brought together to form an input surface 1405 (
Turning to
Typically, each light guide magnifying layer, e.g. magnifying layers 400, 402, 404, 406, 408 and 410, has a width equal to the width of one light guide. In at least one embodiment, the width of the light guide is typically 50-200 micrometers. In at least one embodiment, curved light guide screen 100 consists of a plurality of individual light guide magnifying layers 400-410. Spacers are used to control the distance between light guide magnifying layers 400-410, and the contour of the curvilinear viewing surface 104. More specifically, the center-to-center distance between any two magnifying layers 400-410 may be controlled, thereby controlling the perceived magnification of a projected image. In at least one embodiment, the center-to-center spacing is controlled such that the magnification across the curvilinear viewing surface 104 is constant. The spacers in
In one embodiment, the lengths “lf” of the front surfaces of each spacer, e.g surface 414, are equal to each other, as are the lengths “lr” of the rear surfaces, e.g. surface 416. Of note, if “lf” is greater than “Ir”, viewing surface 104 is generally convex, however, if “lf” is less than “lr”, a concave shaped viewing surface 104 results. If all lengths “lf” are the same, and the lengths “lr” vary, a viewing surface 104 with a curvilinear shape with varying radius of curvature is established. In at least one embodiment, the length “lf” is selected such that the center-to-center distance between magnifying layers 400-410 in a circumferential direction is substantially equal to the elliptical elongation of the output end (e.g. output end 116 in
As shown in reference diagram 500, curved light guide screen 100 is sectioned along line 502 to render the view presented in
Still referring to
Each spacer, provides two non-parallel surfaces, such as for example sides 522 and 526 of spacer 512. There is at least one point of contact between a side 522 of spacer 512 and a side 524 of light guide magnifying layer 400. Similarly, a second side 526 of spacer 512 contacts a side 528 of light guide magnifying layer 402. As with light guide magnifying layer 400, there are one or more points of contact between spacer side 526 and side 528. Spacers 512-520 may be joined to respective magnifying layers 402-410 at or near the magnifying output ends, e.g. output end 510. The shape of spacer 512 is optimized to provide maximum contact while maintaining the desired spacing between light guide magnifying layers 400 and 402.
In particular, for the embodiment illustrated, spacer 512 has a substantially inverted “V”-shaped outline with legs 530 and 532 of spacer 512 shaped and curved as desired to establish/maintain contact with light guide magnifying layers 400 and 402 respectively. The “open end” 534 of the inverted “V” is toward curvilinear viewing surface 104. In this configuration, spacer 512 is tapered, and more specifically spacer 512 tapers away from viewing surface 104. In at least one alternative embodiment, as shown for example in
With respect to
Cross-referencing for a moment
In at least one alternative embodiment, spacers 512-520 retain their shape solely while pressure, represented by arrows 602 and 604 in
In
It can be appreciated by referring to
In at least one embodiment, as an alternative to the inverted “V” spacer shown in
Moreover, spacers 802˜810 may be viewed as being tapered spacers. Each spacer provides two non-parallel surfaces, such as sides 822 and 824 in the case of spacer 804. As shown, the narrow end of the spacer points towards the curvilinear viewing surface 104. Although shown as a “V” with an open rearward section, in at least one alternative embodiment, spacers 802˜810 may be substantially solid wedges, tapering towards the curvilinear viewing surface 104.
The sides of any given spacer positioned between two light guide magnifying layers are still in contact with the two adjacent light guide magnifying layers. For example, in
Use of semi-rigid or rigid spacers in at least one embodiment is highlighted once again in
In contrast to
In at least one alternative embodiment, the spacers may have the shape of “W/M” or a “corrugated” shape as shown in
In one embodiment, spacers 1000, 1002, 1004, 1006 and 1008 are positioned with an open end, e.g. open end 1010, positioned toward curvilinear viewing surface 104. Alternatively, the spacers 1000-1008 may be reversed (not shown) with open ends toward the rear 1011 of case 102 (
It can be appreciated that a “corrugated” shaped spacer may be used to provide spacing that is substantially uniform between light guide magnifying layers, e.g. light guide magnifying layers 1012 and 1014. In this configuration, light guide magnifying layers 1012 and 1014 may be spaced further apart than with the use of a similar sized “V” shaped spacer.
As with the “V” spacers discussed above, the shape of a “corrugated” shaped spacer may be permanently defined during manufacture of the spacer, or it may be changed by applying pressure to the spacer, as shown in
Referring now to
Within a typical light guide 200 (see
In at least one embodiment where such redirection is desired, such redirection of light is accomplished with a light redirection layer. In at least one embodiment, the light redirection layer is a louver layer (not shown) which redirects light emitting from magnifying output ends 1212-1216 toward observer 106. A method for making a louver layer is described in patent application Ser. No. 11/052,612, filed Feb. 7, 2005, entitled “Method of Making A Louver Device for A Light Guide Screen”, which is herein incorporated by reference. Various types of louver layers are described in patent application Ser. No. 11/052,605, filed Feb. 7, 2005, entitled “Holographic Louver Device for A Light Guide Screen,” which is herein incorporated by reference.
In typical embodiments, as the light guide magnifying layers are fabricated as planar structures with parallel surfaces, it is the existence of the two non-parallel surfaces provided by the spacers which permit the advantageous curvilinear viewing surface 104 to be conformed as desired. In addition to the inverted “V” shaped spacers 1206-1210 shown in
These shapes may include the “V” shaped spacer, the “corrugated” spacer, a “U” shaped spacer 1300 (
In operation of curved light guide screen 100, an image is projected upon output curvilinear viewing surface 1400 (
Image source 1402 may be any device capable of providing a visual image, such as, for example, a projector. Image source 1402 is not limited simply to this example, and may also include combinations of devices. For example, multiple light/image sources (such as red, green and blue illuminated liquid crystal light vales) may be used as well.
It is appreciated that input face 1404 exposes a plurality of light guides 1408 to image source 1402. The plurality of light guides 1408 transmit an image generated by image source 1402 to the curvilinear viewing surface 1400 where a magnification of the image is projected toward one or more observers (not shown).
Having discussed the above physical embodiments of a curved light guide screen 100, an embodiment relating to a method of making a curved light guide screen 100 will now be summarized with reference to the flowchart of
As indicated in block 1500, the fabrication process commences by defining the radius of curvature desired/required for the curved light guide screen 100. As stated previously, the curve may be concave, convex, or a more complex shape of varying radius of curvature depending on the desired use for the LGS system. Once the radii of curvature are defined, a plurality of light guides is provided, block 1502.
More specifically, in at least one embodiment the light guides, e.g. light guides 300-304 in
The plurality of input ends are aligned as an input face, block 1504. Further, spacers, e.g. spacer 512 (
Changes may be made in the above methods, systems and structures without departing from the scope thereof. It should thus be noted that the matter contained in the above description and/or shown in the accompanying drawings should be interpreted as illustrative and not in a limiting sense. The following claims are intended to cover all generic and specific features described herein, as well as all statements of the scope of the present method, system and structure, which, as a matter of language, might be said to fall therebetween.
This application is related to commonly owned U.S. patent application Ser. No. 10/698,829, filed on Oct. 31, 2003 and entitled “Light Guide Apparatus For Use In Rear Projection Display Environments”, herein incorporated by reference.