Image projection system with a polarizing beam splitter

Optics: image projectors – Polarizer or interference filter

Reexamination Certificate

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Details

C359S486010

Reexamination Certificate

active

06447120

ABSTRACT:

BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to an image projection system operable within the visible spectrum which includes a polarizing beam splitter which reflects one linear polarization of light and transmits the other. More particularly, the present invention relates to such an image projection system with a beam splitter that is comprised of a plurality of elongated, reflective elements which are disposed on a substrate in such a way to reduce geometric distortions, astigmatism and/or coma in the resulting light beam, and/or which are embedded or otherwise configured to protect the elements.
2 . Related Art
Polarized light is necessary in certain applications, such as projection liquid crystal displays (LCD). Such a display is typically comprised of a light source; optical elements, such as lenses to gather and focus the light; a polarizer that transmits one polarization of the light to the liquid crystal array; a liquid crystal array for manipulating the polarization of the light to encode image information thereon; means for addressing each pixel of the array to either change or retain the polarization; a second polarizer (called an analyzer) to reject the unwanted light from the selected pixels; and a screen upon which the image is focused.
It is possible to use a single polarizing beam splitter (PBS) to serve both as the first polarizer and the second polarizer (analyzer). If the liquid crystal array is reflective, for example a Liquid Crystal On Silicon (LCOS) light valve, it can reflect the beam that comes from the polarizer directly back to the polarizer after encoding the image by modifying the polarization of selected pixels. Such a system was envisioned by Takanashi (U.S. Pat. No. 5,239,322). The concept was elaborated by Fritz and Gold (U.S. Pat. No. 5,513,023). These similar approaches would provide important advantages in optical layout and performance. Neither, however, has been realized in practice because of deficiencies in conventional polarizing beam splitters. The disadvantages of using conventional polarizing beam splitters in projection liquid crystal displays includes images that are not bright, have poor contrast, and have non-uniform color balance or non-uniform intensity (due to non-uniform performance over the light cone). In addition, many conventional polarizing beam splitters are short-lived because of excessive heating, and are very expensive.
In order for such an image projection system to be commercially successful, it must deliver images which are significantly better than the images provided by conventional cathode ray tube (CRT) television displays because it is likely that such a system will be more expensive than conventional CRT technology. Therefore, the image projection system must provide (1) bright images with the appropriate colors or color balance; (2) have good image contrast; and (3) be as inexpensive as possible. An improved polarizing beam splitter (PBS) is an important part of achieving this goal because the PBS is a limiting component which determines the potential performance of the display system.
The PBS characteristics which significantly affect the display performance are (1) the angular aperture, or the f-number, at which the polarizer can function; (2) the absorption, or energy losses, associated with the use of the PBS; and (3) the durability of the PBS. In optics, the angular aperture or f-number describes the angle of the light cone which the PBS can use and maintain the desired performance level. Larger cones, or smaller f-numbers, are desired because the larger cones allow for more light to be gathered from the light source, which leads to greater energy efficiency and more compact systems.
The absorption and energy losses associated with the use of the PBS obviously affect the brightness of the system since the more light lost in the optics, the less light remains which can be projected to the view screen. In addition, the amount of light energy which is absorbed by the polarizer will affect its durability, especially in such image projection systems in which the light passing through the optical system is very intense, on the order of watts per square centimeter. Light this intense can easily damage common polarizers, such as Polaroid sheets. In fact, the issue of durability limits the polarizers which can be used in these applications.
Durability is also important because the smaller and lighter the projection system can be made, the less expensive and more desirable is the product. To accomplish this goal, however, the light intensity must be raised even higher, further stressing the PBS, and shortening its useful life.
A problematic disadvantage of conventional PBS devices is poor conversion efficiency, which is the primary critical performance factor in displays. Conversion efficiency is a measure describing how much of the electrical power required by the light source is translated into light intensity power on the screen or panel that is observed by people viewing it. It is expressed as the ratio of total light power on the screen divided by the electrical power required by the light source. The conventional units are lumens per watt. A high ratio is desirable for a number of reasons. For example, a low conversion efficiency will require a brighter light source, with its accompanying larger power supply, excess heat, larger enclosures and cabinet, etc. In addition, all of these consequences of low conversion efficiency raise the cost of the projection system.
A fundamental cause of low conversion efficiency is poor optical efficiency, which is directly related to the f-number of the optical system. A system which has an f-number which is half the f-number of an otherwise equivalent system has the potential to be four times as efficient in gathering light from the light source. Therefore, it is desirable to provide an improved polarizing beam splitter (PBS) which allows more efficient harvesting of light energy by offering a significantly smaller potential f-number (larger angular aperture), and therefore increases the conversion efficiency, as measured in lumens/watt.
There are several reasons for the poor performance of conventional polarizing beam splitters with respect to conversion efficiency when they are used as beam splitters in projection systems. First, current beam splitters work poorly if the light does not strike them at a certain angle (or at least, within a narrow cone of angles about this principal angle of incidence). Deviation of the principal ray from this angle causes each type of polarizing beam splitter to degrade the intensity, the purity of polarization, and/or the color balance. This applies to the beam coming from the light source as well as to the beam reflected from the liquid crystal array. This principal angle depends upon the design and construction of the PBS as well as the physics of the polarization mechanism employed in these various beam splitters. Currently available polarizing beam splitters are not capable of operating efficiently at angles far from their principal polarizing angles in the visible portion of the electromagnetic spectrum. This restriction makes it impossible to implement certain promising optical layouts and commercially promising display designs.
Even if the principal ray strikes the polarizer at the best angle for separating the two polarizations, the other rays cannot diverge far from this angle or their visual qualities will be degraded. This is a serious deficiency in a display apparatus because the light striking the polarizer must be strongly convergent or divergent to make efficient use of the light emitted by typical light sources. This is usually expressed as the f-number of the optical system. For a single lens, the f-number is the ratio of the aperture to the focal length. For optical elements in general, the F-number is defined as
F/#=1/(2 n sin &THgr;)
where n is the refractive index of the space within which the optical element is located, and &THgr; is the half cone angle. The sm

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