WO1993025922A1

WO1993025922A1 - Method and means for reflecting a predetermined range of wavelengths of a beam of light

Info

Publication number: WO1993025922A1
Application number: PCT/US1993/005592
Authority: WO
Inventors: Steven R. Sedlmayr
Original assignee: Sedlmayr Steven R
Priority date: 1992-06-11
Filing date: 1993-06-10
Publication date: 1993-12-23
Also published as: US5347433A; AU4533293A

Abstract

A method and system for reflecting a predetermined range of wavelengths of a beam of light (50) while transmitting the remaining range of wavelengths without changing the orientation of an electric field vector for the reflected or transmitted wavelengths is disclosed. The system and method are particularly suited for use in a PEMFVORD projection system for illuminating rectangular shaped LCDs (34) of the projection system. A system of the invention permits virtually all of the light from a light source (32) to be directed at the LCDs (34) and can be used to provide a projection system having improved brightness, contrast and resolution with better heat dissipation.

Description

METHOD AND MEANS FOR REFLECTING A

PREDETERMINED RANGE OF

WAVELENGTHS OF A BEAM OF LIGHT

Field of the Invention This invention relates to a method and means for (i) reflecting a predetermined range of wavelengths of a beam of light while transmitting the remaining range of wavelengths of the beam of light without changing the orientation of electric field vector for the reflected and transmitted ranges of wavelengths, (ii) reflecting each of two or more predetermined ranges of wavelengths of a beam of light from a respective one of two coated elements while transmitting the remaining portion of each unreflected range of wavelengths of the beam of light through the respective coated elements without changing the orientation of electric field vector of the reflected and transmitted ranges of wavelengths, (iii) reflecting a predetermined range of wavelengths of a beam of light and changing the orientation of electric field vector of the reflected range of wavelength by a predetermined amount, and (iv) reflecting each of two or more predetermined ranges of wavelengths of a beam of light from a respective one of two coated elements while changing the orientation of electric field vector of the reflected ranges of wavelengths, and in particular the above usages in relation to a projection type color display device. This invention also relates to a filter means comprising an element and a coating and a mirror means formed from an element and a dielectric coating.

Background of the Invention

A disturbance (change in position or state of individual particles) in the fabric of space-time causes a sphere of influence. Stated in a simplistic manner,^" the action of one particle influences the actions of the others near it. This sphere of influence is referred to as a "field", and this field is designated as either electric or magnetic (after the way it influences other particles) . The direction of travel of the particle is called the direction of propagation. The propagation of the particle, the sphere of influence, and the way it influences other particles is called an electromagnetic wave, and is shown in Figure 1. As shown in Figure 1, the electric and magnetic fields are orthogonal (at right angles) to each other and the direction of propagation. These fields can be mathematically expressed as a vector quantity

(indicating the direction of influence along with strength, i.e. , magnitude, of influence) at a specific point or in a given region in space. Thus, Figure 1A is the electromagnetic wave in Figure 1, but with the view of looking down the axis of propagation, that is, down the x axis of Figure 1. Figure 1A shows some possible various electric field vectors that could exist, although it should be understood that any and all possible vectors can exist around the circle, each having different magnitudes.

Vectors can be resolved into constituent components along two axes. This is done for convenience sake and for generating a frame of reference that we, as humans, can understand. By referring to Figure IB, it is shown that the electric field vector E, can be resolved into two constituent components, E(y) and E(x) . These quantities, then, describe the orientation and the magnitude of the electric field vector along two axes, the x and y, although other axes or systems could be chosen. The same applies to magnetic fields, except that the X and Z axes would be involved. The way the electric and magnetic fields vary with time in intensity and direction of propagation have been determined by several notable mathematicians and physicists, culminating in a group of basic equations by James Maxwell. These equations, simply applied, state that a field vector can be of one of several different states, that is: 1) the field vector varies randomly over a period of time, or 2) the field vector can change directions in a circular manner, or 3) the field vector can change directions in a elliptical manner, or 4) the field vector can remain constant in magnitude and direction, hence, the field vector lies in one plane, and is referred to as planar.

This orientation of a field vector and the way it changes with time is called the state of polarization.

Electromagnetic waves can be resolved into separate electromagnetic waves with predetermined orientations of a field vector. The electromagnetic waves with a predetermined orientation of a field vector can then be directed through materials, such as a liquid crystal device, that is capable of changing (or altering) their orientation of the field vector upon application of an outside stimulus, as is demonstrated in Figure 7. These devices are noted as programmable electromagnetic wave field orientation rotating devices (PEMFVORD) .

An electromagnetic wave can be characterized by its frequency or wavelength. The electromagnetic spectrum (range) extends from zero, the short wavelength limit, to infinity, the long wavelength limit. Different wavelength areas have been given names over the years, such as cosmic rays, alpha rays, beta rays, gamma rays, X-rays, ultraviolet, visible light, infrared, microwaves, TV and FM radio, short wave, AM, maritime communications, etc. All of these are just short hand expressions of stating a certain range of frequencies for electromagnetic waves.

Different areas of the spectrum interact with electromagnetic influences upon them in various proportions, with the low end being more influenced by magnetic fields, and the high end being influenced by electric fields. Thus, to contain a nuclear reaction, a magnetic field is used, while controlling light an electric field is used. Figure 2 illustrates a schematic cross section of an LCD cell. The LCD cell 100 includes a liquid crystal material 101 that is contained between two transparent plates 103, 104. Spacers 105, 106 are used to separate the transparent plates 103, 104. Sealing elements 107, 108 seal the liquid crystal material 101 between the transparent plates 103, 104. Conductive coatings 109, 110 on the transparent plates 103, 104 conduct the appropriate electrical signals to the liquid crystal material 101. A type of liquid crystal material 101 used in most LCD cells for optical display systems is referred to as "twisted nematic." In general, with a twisted nematic LCD cell, the molecules of an LCD cell are rotated in the absence of a field through a 90° angle between the upper 103 and lower 104 transparent plates. When a field is applied, the molecules are untwisted and line up in the direction of the applied field. The change in alignment of the molecules causes a change in the birefringence of the cell. In the homogeneous ordering, the birefringence of the cell changes from large to small whereas the opposite occurs in the homeotropic case. The change in birefringence causes a change in the orientation of the electric field vector for the light being passing through the LCD. The amount of the rotation in the molecules for an individual LCD cell 100. will determine how much change in polarization (orientation of the electric field vector) of the light occurs for that pixel. The light beam is then passed through another component of the system (i.e., polarizer analyzer) and is resolved into different beams of light by the orientation of their electric field vectors, with the light that has a selected predetermined component of the electric field vector passing through to finally strike the screen used for the display. A twisted nematic LCD cell requires the light incident at the LCD cell 100 to be polarized. The polarized light for a typical projector is generally derived from a randomly polarized light source that is colli ated and then filtered by a plastic polarizer to provide a linear polarized beam. Linear polarized beams are conventionally referred to as being S-polarized and P-polarized with the P-polarized beam defined as polarized in a direction parallel to the plane of incidence and the S-polarized beam defined as polarized perpendicular to the plane of incidence.

The development of PEMFVORD technology has resulted in the development of LCD projectors which utilize one or more LCDs to alter the orientation of the electric field vector (aee Figure 7) of the light being projected. The birefringence of the individual LCD pixels are selectively altered by suitable apparatus such as cathode ray tubes, lasers, or electronic circuit means. A typical LCLV projector includes a source lamp which is used to generate a light beam that is directed through a polarizer. This polarized light is directed through the LCDs to change the polarization according to the image to be displayed. The light, after exiting the LCD, passes through a plastic polarizer analyzer which stops and absorbs the unwanted portion of light. The formed image is then enlarged with a projection lens system for forming an enlarged picture on a display screen.

Color LCLV projectors typically include color separating apparatus such as a prism, beam splitters or dichroic mirrors to separate collimated white light beams from the light source into three primary color beams {i.e. , red, green and blue beams). The red, green and blue beams are then individually modulated by LCDs and combined by separate optical apparatus such as combining prisms, mirrors or lenses.

In general, the quality and brightness of the projected image in any liquid crystal light valve (LCLV) projector is a function of the brightness of the source for illuminating the LCDs and the polarizing means. Polarizing optics must be utilized to filter/separate the white light into light with a single orientation of the electric field vector. The white light emitted from the source is thus only partially utilized (i.e. , one direction of polarization) in most LCLV projection systems. This requires oversized light sources to achieve a desired brightness at the viewing screen.

Typically, with a twisted nematic transmissive type LCD cell surrounded by plastic polarizers, only forty percent or less of the output of the light βource is utilized. Practically, only a maximum transmission of 50% for randomly polarized ligh -passed through could ever be achieved because of the construction and principles involved in plastic polarizers, allowing for 100% efficiency for the device for all wavelengths. Thus, it is impossible to obtain a full brightness projector. Moreover, the unused polarized component of the light source is absorbed by the plastic polarizers and generates wasted energy in the form of heat and transfers this heat to other components (i.e., LCDs, electronics, etc.) and hence is detrimental to the system (especially the plastic polarizers, LCDs, electronics, etc.). This heat must be either shielded and/or dissipated from the components of the system, or else, the light source must be reduced in light output so that the amount of light being absorbed is below the threshold of permanent damage to the components, including the plastic polarizers. Currently, this threshold for fabricated plastic polarizers is between the range of 5-10 watts of light per square inch (.78-1.55 watts per square centimeter), depending upon the wavelength of the illuminating light. A method for improving the damage threshold is included in U.S. Patent No. 5,071,234 to Amano, et al. , although this patent does not discuss the particulars of what the damage threshold is.

Prior art systems have required relatively complicated optical systems including the use of polarizing prisms and prepolarizing prisms to ensure a unitary or single polarization at the LCD and to provide a suitable resolution and contrast of the projected image. With prior art color LCLV projectors, complicated optic components and arrangements are required to combine the separated color bands at a suitable resolution and contrast. Representative prior art LCLV projectors are disclosed in U.S. Patent No. 5,060,058 to Goldenberg, et al. , U.S. Patent No. 5,048,949 to Sato, et al., U.S. Patent No. 4,995,702 to Aruga, et al., U.S. Patent No. 4,943,154 to Miyatake, et al. , U.S. Patent No. 4,936,658 to Tanaka, et al. , U.S. Patent No. 4,936,656 to Yamashita, et al. , U.S. Patent No. 4,935,758 to Miyatake, et al. , U.S. Patent No. 4,911,547 to Ledebuhr, U.S. Patent No. 4,909,601 to Yajima, et al. , U.S. Patent No. 4,904,061 to Aruga, et al. , U.S. Patent No. 4,864,390 to McKechnie, U.S. Patent No. 4,861,142 to Tanaka, et al. , U.S. Patent No. 4,850,685 to Kamakura, U.S. Patent No. 4,842,374 to Ledebuhr, U.S. Patent No. 4,836,649 to Ledebuhr, et al. , U.S. Patent No. 4,826,311 to Ledebuhr, U.S. Patent No. 4,786,146 to Ledebuhr, U.S. Patent No. 4,772,098 to Ogawa, U.S. Patent No. 4,749,259 to Ledebuhr, U.S. Patent No. 4,739,396 to Hyatt, U.S. Patent No. 4,690,526 to Ledebuhr, U.S. Patent No. 4,687,301 to Ledebuhr, U.S. Patent No. 4,650,286 to Koda, et al. , U.S. Patent No. 4,647,966 to Phillips, et al, U.S. Patent No. 4,544,237 to Gagnon, U.S. Patent No. 4,500,172 to Gagnon, U.S. Patent No. 4,464,019 to Gagnon, U.S. Patent No. 4,464,018 to Gagnon, U.S. Patent No. 4,461,542 to Gagnon, U.S. Patent No. 4,425,028 to Gagnon, U.S. Patent No. 4,191,456 to Hong, et al. , U.S. Patent No. 4,127,322 to Jacobson, et al. , U.S. Patent No. 4,588,324, to Marie, U.S. Patent No. 4,943,155 to Cross, Jr., U.S. Patent No. 4,936,657 to Tejima, et al , U.S. Patent No. 4,928,123 to Takafuji, U.S. Patent No. 4,922,336 to Morton, U.S. Patent No. 4,875,064 to Umeda, U.S. Patent No. 4,872,750 to Morishita, U.S. Patent No. 4,824,210 to Shimazaki, U.S. Patent No. 4,770,525 to Umeda, et al , U.S. Patent No. 4,715,684 to Gagnon, U.S. Patent No. 4,699,498 to Naemura, et al. , U.S. Patent No. 4,693,557 to Fergason, U.S. Patent No. 4,671,634 to Kiza i, et al. , U.S. Patent No. 4,613,207 to Fergason, U.S. Patent No. 4,611,889 to Buzak, U.S. Patent No. 4,295,159 to Carollo, et al.

Other systems, such as those disclosed in U.S. Patent No. 4,824,214 to Ledebuhr, U.S. Patent No. 4,127,322 to Jacobson, et al. , U.S. Patent No. 4,836;649 to Ledebuhr, et al. , and U.S. Patent No. 3,512,868 to Gorklewiez, et al. also disclose optical layouts for achieving a high brightness in display systems that utilize LCD devices. In general, these systems are relatively complicated and contain numerous components that are large, expensive, and difficult to adjust.

Brief Summary of the Invention ε In accordance with the present invention, a method and means for reflecting a predetermined range of wavelengths of a beam of light while transmitting the remaining range of wavelengths of the beam of light without changing the orientation of electric field 0 vector for the reflected and transmitted ranges of wavelengths which in turn can illuminate a PEMFVORD, and/or a PEMFVORD projector. The system and method are particularly useful in projection systems that employ PEMFVORD projector having a rectangular peripheral 6 configuration.

One illustrative embodiment used to demonstrate the purposes of the invention comprises: a light source for producing a collimated unpolarized beam of light; a polarizing beam splitter for splitting the unpolarized 0 source beam into separate orthogonal linear P-polarized and S-polarized light beams; a half-wave retarder for converting the S-polarized light beam back to a second polarized-polarized light beam; and an arrangement of mirrors that combines the P-polarized light beams into 5 a rectangular shaped beam of a unitary polarization.

The light beam, at this point, is separated into a red component and into a blue-green component using a first dichroic mirror selected to reflect light having red wavelengths greater than 600 nanometers. The o blue-green component is then separated into a blue beam and a green beam using a second dichroic mirror selected to reflect light having green wavelengths between 500 nanometers and 600 nanometers. As an option, the red beam and the.blue beam can be further filtered in order to provide an optimum of color balance in visual effect and the rejected portions of the beams that are filtered out from the red and blue can then be absorbed. At this point, the separate red, green and blue beams are passed through liquid crystal display devices and have their electric field vectors altered according to the input signal. The separate red and green beams are combined into a red-green beam using a dichroic mirror selected to pass the green beam wavelengths less than 595 nanometers and reflect the red beam. This red-green beam is then combined with a separate blue beam utilizing another dichroic mirror selected to pass the red-green beam wavelengths greater than 515 nanometers and reflect the blue beam to form a collinear beam. This collinear beam is then passed through a polarizer analyzer to segregate the beam according its electric field vector. One of the segregated beams can be passed to an absorbing beam block. The selected segregated modulated polarized beam is passed onto a projection lens that projects it onto a viewing screen. The system and method of invention can be adapted for projecting a large image of high brightness, resolution and contrast onto a screen.

It should be further understood that, while certain particular wavelength numbers have been given for red, blue and green, they are for illustrative purposes only and can be changed or shifted due to the type of light source uβed. The changing or shifting of the particular range of wavelengths of the colors is due to the final color balance that is desired.

In use of one system used for demonstration of this invention, collimated light from the light source is directed through the polarizing beam splitter. The polarizing beam splitter separates the randomly polarized beam into a linear P-polarized beam and S-polarized beam and deflects the orthogonal polarized beams at right angles to one another. The P-polarized beam passes through the polarizing beam splitter and is reflected through an angle of 90° by a first mirror and into the projector beam path. The S-polarized beam exits from the polarizing beam splitter at an angle of 90° to the P-polarization beam and passes through the half-wave retarder. The half-wave retarder changes the polarization of the S-polarized beam back to P-polarization. A second mirror then reflects this P-polarized beam through an angle of 90° onto a third and a fourth mirror. The third and fourth mirrors split the reflected P-polarization beam and again reflect the P-polarized light beam from the second mirror through an angle of 90° and onto the LCD. The four mirrors are mounted along an optic path with respect to one another such that the separate P-polarized beams are combined in a generally rectangular shaped beam that corresponds to the rectangular light aperture of a LCD. The system of the invention permits virtually all the light from the light source to be directed at the LCD. Moreover, the light beam at the LCD has a shape that corresponds to the generally rectangular outer peripheral configuration of most LCDs. The advantages of the rectangular beam allow the utilized light to strike the useful portions of t'he LCD, thereby not overheating the other elements surrounding the LCD causing reflection and/or heating problems.

In light of the previous discussions and further in the description and claims, it will become apparent that the following partial list of the advantages of the invention are:

High brightness is easily achieved: brightness is limited only by the LCD characteristics; brightness can be easily modified by changing light sources. Improved efficiency means lower heat; a high efficiency optical path is utilized and the only significant heating in the optics is due to LCD absorption. Modifications are simple; optics can accommodate any intensity and variety of light sources.

Color resolution and registration is easily adjusted.

Mirrors add to improved polarization of light beams.

Mirrors have long life and longevity

Other objects, advantages and capabilities of the present invention will become more apparent as the description proceeds.

Brief Description of the Drawings

Figure 1 is an illustrative drawing of an electromagnetic wave with the direction of propagation, electric and magnetic fields shown.

Figure 1A is an illustrative drawing of looking at an electromagnetic wave down the axis of propagation, showing various directions of possible different orientations of the electric field vector for illustrative purposes.

Figure IB is an illustrative drawing of the resolution of an electric field vector into two components, along an x and y axis.

Figure 2 is a cross-section of an LCD cell as is known in the art.

Figure 2A is an schematic drawing of an LCD component showing pixels.

Figure 3 is a schematic illustration of a system for illuminating an LCD display or LCDs in a LCLV Projector. Figure 3A is an alternate schematic illustration of a system for illuminating an LCD display or LCLV Projector similar to that shown in Figure 3.

Figure 3B is a preferred embodiment of a schematic illustration of a system for illuminating an LCD display or LCLV Projector similar to that shown in Figures 3 & 3A.

Figure 3C is an alternate schematic illustration of a system for illuminating an LCD display or LCLV Projector similar to that shown in Figures 3, 3A & 3B. Figure 4 is a schematic of a collimated light beam from a light source superimposed upon a mirror.

Figure 4A is a diagrammatic representation used in an analysis of the geometry of an LCD light aperture and a light beam.

Figure 5 is a schematic showing the shape of a light beam of a unitary polarization superimposed upon on an LCD display.

Figure 6 is an illustrative drawing showing several layers of a thin film coating be illuminated by a non-polarized wave source and the resulting polarized beam.

Figure 7 is an illustrative drawing depicting a polarized beam impinging upon a LCD cell and the resulting retardation (changing, altering, or twisting) of the electric field vector.

Figure 8 is a preferred embodiment of a diagrammatic representation of a color LCLV projector. Figure 8A is a functional illustration of Figure 8 according to the nomenclature used in the claims for the various parts, methods and means, and shows everything grouped according to the function it performs. However, it should be understood that other parts, methods and means may be substituted or deleted as needed, and that this diagram is not meant to be limiting in any fashion or manner.

Figure 9 is a graph showing the spectral characteristics of commonly used optical sources. Figure 9A is a table showing the performance data of common optical sources.

Figure 10 is a graph illustrating the scotopic and photopic response characteristics for the human eye of visible light. Figure 10A is an illustration showing the CIE color diagram.

Figure 10B is the same as Figure 10A but shows the different colors given to the various regions.

Figure 11 is a graph showing a wavelength response of polarizing cube component used in an illustrative embodiment of the invention.

Figure 12 is a graph of the transmissive and reflective characteristics of a mirror (33) used in an illustrative embodiment of the invention for separating an infrared component of a source beam.

Figure 13 is a graph of the transmissive and reflective characteristics of a mirror (35) used in an illustrative embodiment of the invention for separating an ultraviolet component of the source beam. Figure 24 is a graph of the transmissive and reflective characteristics of mirrors (80 & 82) used in an illustrative embodiment of the invention for separating and further filtering a red light component of the source beam. Figure 15 is a graph of the reflective and transmissive characteristics of mirror (90) used in an illustrative embodiment of the invention for combining an altered blue beam and an altered red-green beam. Figure 16 is an analysis of the reflective and transmissive characteristics of mirror (92) for combining an altered red beam and an altered green beam.

Figure 17 is an analysis of the reflective and transmissive characteristics of mirrors (86 & 88) for further filtering a blue beam.

Figure 18 is an analysis of the reflective and transmissive characteristics of a mirror (84) for further filtering a blue beam.

Detailed Description of the Preferred Embodiments

For purposes of simplicity, the same number has been used in the various figures to identify the same part.

Referring now to Figure 3, a collimated light beam from a light source 32 is converted into a unitary polarized beam having a shape that matches an outer peripheral configuration of the LCD display 34. As an example, the LCD 34 display is a LCD having a light aperture of a generally rectangular outer peripheral configuration.

This aspect of the invention includes in an optically aligned path: a polarizing beam splitter 36, a half-wave retarder 38, and an arrangement of a first mirror 40, a second mirror 42, a third mirror 44, and a fourth mirror 46, that combine the separate beams exiting from the polarizing beam splitter 36 into a combined beam of single polarization 30 having a shape that matches the shape of the LCD display 34. Suitable color filters 48 can be placed between the LCD display 34 and the combined beam.

The manner in which the collimated beam 50 is formed is now described. Light source 32 and reflector 41 produce an unpolarized beam of light 50 which is then collimated by collimation optics, such as lens 43 or light integrator 63.

Referring to Figure 3, the light source 32 and its reflecting optics 41 form an unpolarized collimated beam of light 50. The unpolarized collimated beam of light 50 is split by the polarizing beam splitter 36 into separate orthogonal polarized beams, a P-polarized beam 52, and an S-polarized beam 54. The P-polarized beam passes through the polarizing beam splitter 36 and is directed onto the first mirror 40 and reflected through an angle of 90° as a reflected beam 53 and onto the LCD display 34. The S-polarized beam 54 is deflected by the polarizing beam splitter 36 through an angle of 90° and is passed through the half-wave retarder 38. The half-wave retarder 38 changes the orientation of the electric field vector of the S-polarized beam 54 to form a second P-polarized beam 56. This second P-polarized beam 56 is reflected through an angle of 90° by the second mirror 42. The third mirror 44 and fourth mirror 46 are situated to intercept the reflected second P-polarized beam 56 and split the beam into two separate reflected beams 58 and 60 emanating in the same direction as reflected beam 53. The three separate reflected beams 53, 58, and 60 are then combined into a single beam 30 having a single orientation of the electric field vector (P-polarized) and is directed through suitable color filters 48 to the LCD display 34.

With reference to Figure 4, each mirror such as first mirror 40, may be configured with a preferred geometrical shape generally rectangular or square (i.e., a square shape is a subset of a rectangular shape) outer peripheral configuration to intercept a generally circular shaped or collimated light beam (i.e. , 52) such that the reflected beam (i.e. , 53) from the mirror is also of a square or rectangular configuration. This arrangement will produce a reflected beam that is geometrically similar to the sizes and shapes of the mirrors used, as the geometry of the mirrors will be duplicated by the reflected beams. . As shown in Figure 5, this allows a square-shaped reflected beam 53 from a first mirror 40, a rectangular shaped reflected beam 60 from fourth mirror 46, and a rectangular shape reflected beam 58 from third mirror 44 to be aligned to produce a unitary beam at the LCD display 34 having a generally rectangular outer peripheral configuration. This rectangular configuration of the unitary beam matches the rectangular outer peripheral configuration of the LCD display 34 and in particular to light aperture of the LCD display 34. The method and system for the invention with reference to Figure 4 can be summarized as follows: producing an unpolarized collimated beam of light 50 with a light source 32; splitting the unpolarized beam of light 50 with a polarizing beam splitter 36 into separate orthogonal polarized beams 52, 54 (i.e. , a first P-polarized beam 52 and an S-polarized beam 54) ; directing a first orthogonal beam 52 (first P-polarized beam 52) onto a first mirror 40 to produce a first reflected beam 53; directing the second orthogonal beam 54 (S-polarized beam 54) through a half-wave retarder 38 in order to convert the direction of polarization of.the second orthogonal beam 54 (S-polarized beam) to a second reflected beam 56 having the same polarization as the first orthogonal beam 52 (a second P-polarized beam) ; directing the second orthogonal beam 56 (second P-polarized beam) onto a second mirror 42 and reflecting the beam through an angle of 90°; directing the second reflected beam 56 onto third and fourth mirrors 44, 46 that reflect the second reflected beam 56 through a second 90° angle and split the second reflected beam 56 into a third reflected beam 58 and a fourth reflected beam 60; and combining the separate reflected beams, i.e. , first reflected (P-polarized) beam 53, third reflected (P-polarized) beam 58 and fourth reflected (P-polarized) beam 60, into a unitary beam of a single polarization and having a rectangular outer peripheral shape that matches the rectangular outer peripheral-shape of an LCD display 34.

Mirrors 40, 42, 44, 46 or other reflecting means are to be aligned to intersect the path of the orthogonal light beams 52, 56 to produce a unitary light beam by the combination of separate reflected beams 53, 58, 60 at the LCD display 34. Figure 3 illustrates just one such alignment pattern for the mirrors 40, 42, 44, 46 with their planar surfaces. In the embodiment illustrated by Figure 3, third mirror 44 and fourth mirror 46 are located on either side of first mirror 40.

Figure 3A illustrates another possible alignment of the mirrors 40, 44 and 46 to intersect the path of the orthogonal light beam 52, 56. In the embodiment of Figure 3A, the third mirror 44 and fourth mirror 46 are both aligned on one side of the first mirror 40. However the resultant unitary beam at the LCD display 34 is functionally the same. Arrangements of the mirrors 40, 44, 46 other than those shown in Figures 3, 3A, & 3C are also possible. The arrangement of mirrors in Figures 3A & 3B are the same. Moreover, the mirrors 40, 44, 46 may be shaped and arranged to produce a square shaped beam at the LCD display 34. Beam 30 allows essentially all of the light produced by the light source 32 to be utilized for illuminating the LCD display 34 taking into consideration the form factor of the light source as shown in Figure 4A and described below. With beam 30, the minimal number of components (i.e. , polarizing beam splitter 36, half-wave retarder 38, mirrors 40, 42, 44, 46) allow these components to be easily adjusted to achieve a resultant unitary beam at the LCD display 34 that is of the desired shape and of a single 6 polarization (i.e., single orientation of the electric field vector) . The polarization of the resultant beam in the illustrative embodiments is in a P-polarized direction. Alternately, the beam 30 can be configured to produce an S-polarized beam at the LCD display 34, or o whatever else predetermined polarization direction is chosen.

In addition, the half-wave retarder 38 may be rotated to tune the polarization of the resultant beam 56 exiting from the half-wave retarder 38 to exactly 6 match the polarization of the first P-polarized beam 52 exiting the polarizing beam splitter 36. Additionally, the positions of the mirrors (40, 42, 44, 46) may be easily adjusted or rearranged to achieve a predetermined resultant beam of a desire outer peripheral o configuration at the LCD display 34.

In Figure 3B, half-wave retardation of the beam is realized by means other than the half-wave retarder 38 as used in Figure 3A. This is accomplished by reflecting the beam 54 (S-polarized) from the second 6 mirror 42, resulting in a quarter-wave retardation. Each half of the beam is then reflected from the respective mirrors 44, 46 and further retarded by a quarter-wave. This results in half wave retardation of S-polarized beam 54 changing it into P-polarized beams 0 58, 60. The system shown in Figure 3B is preferred to those systems shown in Figures 3 £ 3A because less components are required. Such mirrors are available from 0CLI Corporation, Santa Rosa, California as part numbers 777-QWM001, through 777-QWM002. The mirrors 42, 44, 46 as shown in Figure 3B can be constructed with a coating formed thereon through thin film coating techniques. Each mirror 42, 44, 46 can act as a quarter wave retarder, besides being a broadband reflector.

Thin film coatings are also referred to as dielectric films, i.e. , they are films made of materials composed of atoms whose electrons are so tightly bound to the atomic nuclei that electric currents are negligible even under applied high electric fields. The individual film thicknesses or layers vary over a very broad range, but they are referred to as a thin film when the thickness of the film is on the order of that wavelength. These films are built up in many layers, one on top of another, and are referred to as a multilayer thin film, as loosely illustrated in Figure 6. Each layer then reflects the appropriate wavelength or orientation of the electric field vector according to its individually designed construction. These layers are typically deposited on top of a receiving substrate by vacuum deposition. This includes vaporizing a material and causing the vapor atoms to strike the substrate in a predetermined manner and rate. Some typical materials are MgF₂, Si0₂, A1₂0₃, C (diamond) , ZnS, Ti0₂, CdS, CdTe, GaAs, Ge, Si, Ag, Au, PbS, along with many other materials.

Because dielectric materials are used, the index of refraction for each layer is different from each adjacent layer, although in some cases they might be the same.

Light is reflected from, and transmitted through each layer (see Figure 6) and interface. These light wave fields that are transmitted and reflected from each interface interact with one another. Depending upon the material chosen for the thin film and the optical thickness of the thin film, different results are achieved. A device made in this fashion can have from one to several hundred film layers on a substrate. In one instance, by proper design, a coating can change the phase of incident linearly polarized light. In effect, this functions as a relative quarter wave plate. Several papers on this subject have been published, but in particular: "Phase Retardance of Periodic Mul tilayer Mirrors, " Appl. Opt., 21(4) :733 (1982), Joseph H. Apfel, "Graphical Method to Design Internal Reflection Phase Retarders, " Appl. Opt., 23(8);1178 (1984), "Mul tilayer Coating Design Achieving a Broadband 90° Phase Shif " , Appl. Opt., 19(16):2688, (1980), William H. Southwell. In another design, the coating reflects the incident polarized light wave, and thus reinforces the p-polarized reflection. This design reflects the entire light spectrum and functions as a broadband mirror.

The components of the system producing beam 30 may be fabricated from commercially available parts. Light source 32 can be any suitable lamp such as a short arc lamp, a quartz-halogen lamp, a mercury vapor/xenon long arc lamp, etc. In general, such lamps efficiently produce a high intensity point source of light. They are available in various sizes and with varying spectral qualities. Suitable commercial embodiments of high brightness light sources (greater than 15,000 lumens) are manufactured by many manufacturers, including but not limited to Optical Radiation Corporation, Azusa, California. Other light sources that produce desired wavelengths and different output lumens (spectra or spectrum distribution) may also be utilized as shown in Figure 9A. Most light sources contain a spectrum of visible, infrared, and ultraviolet light that are contained in.different proportions respective to each other. Lasers can also be used as light sources. Polarizing beam splitter 36 may be any of the known devices. It may be, for example, composed of a dielectric thin film stack disposed on a suitable substrate (such as glass) . The stack may be fabricated by alternating layers of high and low refractive index films each with a quarter-wave optical thickness, with the center of the wavelength design for visible light at approximately 550 nanometers. At each film/film interface, light is incident at Brewsters angle which transmits P-polarized light and reflects S-polarized light. The number of layers are dependent upon the final outcome desired, and can be tailored for the cost/performance tradeoff desired. It may be fashioned in the shape of a cube of glass with the layers deposited on the diagonal, or alternatively, the multilayers can be deposited on a piece of glass, and optionally, another piece of glass can then be cemented to the front, forming a sandwich of which the multilayers are deposed in between the two pieces of glass. The purpose of this is to protect the layer stack from abrasion or contact with the air. The arrangement of a single piece of glass or two pieces of glass would yield a polarizing beam splitter that is less costly to produce and weigh less than a cube polarizer.

It is preferred that the light striking the surface of the layers do so at a 45° angle, with a small deviation from the normal of the rays, thus the incidence angle between the layers and the beam of light should be well controlled. Such a polarizing beam splitter is described in U.S. Patent No. 2,403,731 to MacNeille or 2,449,287 to Flood and is termed a MacNeille polarizer. A commercial embodiment of such a polarizing beam splitter suitable for use herein can be obtained from the Perkin Elmer Corporation, Electro-Optical Division, Norwalk, Connecticut or OCLI Corporation, Santa Rosa, California. A wavelength response for a polarizing beam splitter is shown in Figure 10. 6 Typically, such coatings of thin film stacks on the diagonal of the polarizers and polarizing beam splitters can be coatings capable of handling high energy beams such as laser beams. They are capable of handling high wattage of incident energy per centimeter squared. o The mirror 40 (OCLI Corporation, Santa Rosa, California, part no. 777-BBM001) must be selected to be an efficient reflector of the P-polarized light at the particular wavelength required. Mirrors 42, 44, 46 are selected to be either quarter wave retarders or 5 broadband reflective mirrors, depending upon how the system is configured. If used as a quarter wave mirror, their part numbers are 777-QWM001 and 777-QWM002. If used as a broadband mirror, their part numbers are 777-BBM002 and 777-BBM003. These mirror numbers are o used by OCLI Corporation, Santa Rosa, California. As an example, the mirrors can be formed of a thin film coated onto a substrate. The thin film is formed with a broadband coating for visible light. It is known that metal film mirrors reflect P-polarized waves more 6 efficiently than S-polarized waves because of the nature of metal reflections. Because of this known efficiency factor, the conversion of S-polarized waves to P-polarized is utilized by this invention.

Such thin film mirrors that are acceptable for use o herein can be obtained from the OCLI Corporation, Santa Rosa, California. Thin film coatings are known as laser coatings and are capable of handling high energy beams (watts divided by centimeters squared) .

The half-wave retarder 38 (shown in Figure 3A) 5 may be one of a class bf optical elements' known, as retarders, which serve to change the polarization of an incident wave. With a retarder, the light exiting has the orientation of the electric field vector lagged in phase behind the input light by a predetermined amount. Upon emerging from the retarder, the relative phase is different than it was initially and thus the polarization state (orientation of the electric field vector) is different as well. A retardation plate that introduces a relative phase difference of 90° is known as a half-wave retarder.

A half-wave retarder can be made from a biaxial crystal material such as mica. Suitable retarders can also be made from sheets of plastic material that have been stretched to align long chain organic molecules, thin film dielectrics (such as that made by OCLI Corporation, Santa Rosa, California) , LCDs, reflection from mirrors coated with a thin film dielectric, a combination of a LCD and a mirror coated with a thin film dielectric, and quartz crystal. The half-wave retarder 38 used in the illustrative embodiment of the invention can preferably be adjusted (i.e. , by rotation of the crystal) to exactly match the polarization state of a P-polarized light beam 56 exiting the retarder 38 (see Figure 3A) with the P-polarization state of P-polarized light beam 52 exiting the polarizer cube 36. Other means of changing or converting the polarization direction of a light beam other than a half-wave retarder can be employed in this application.

By way of example and not limitation, a system and method constructed in accordance with the invention offers the following results and advantages over prior art illumination systems:

A rectangular singularity polarized beam is created that will efficiently fill the aperture of an LCD display; The divergence of the resultant beam at the LCD display is smaller than with other methods of combination, i.e., U.S. Patent No. 4,913,529 to Goldenberg. Referring now to Figure 8, a projector constructed in accordance with an illustrative embodiment of the invention is shown. Figure 8 is labeled with locative directions illustrating an optic path for convenience sake only and does not necessarily resemble what the actual layout may be. Other arrangements of the illustrative components connected in different optic paths may also be suitable.

A light source 32 (i.e. , a xenon short arc lamp, a quartz-halogen lamp, a mercury vapor/xenon long arm lamp, etc.) emits light which is collimated into a source beam of white light 50 traveling toward the left that contains a wavelength spectrum of visible, infrared and ultraviolet light. (Most light sources contain all of the above wavelengths of light; however, they are contained in different proportions respective to each other. See Figures 9 & 9A for different types of light sources) . Depending on the application, the lamp source can be any suitable means for producing a collimated beam of light. The characteristics of the light source may be tailored to a particular application.

The visible region of light that a typical person can see is between 400 and 700 nanometers in wavelength (this is well understood and can be found in standard reference books or college level text books (see also photopic response curve in Fi_τure 10) . The non-visible wavelengths between 200 nanometers to 400 nanometers are named the ultraviolet region and the non-visible wavelengths between 700 nanometers and 1500 nanometers are.named the infrared region. The infrared wavelength region -(greater than 700 nanometers) and the ultraviolet wavelength region (less than 400 nanometers) each contribute watts of radiant light energy which are detrimental to the optics of the system but does not contribute to normal human eyesight (see photopic response curves in Figure 10) . Because of this fact, the collimated source beam 50 from the light source 32 is directed to the left toward mirror 33 which is a dichroic/thin film dielectric mirror. Dichroic/thin film dielectric mirrors are able to function as wavelength filters. In general, these type of mirrors are constructed to transmit (i.e., pass through) all light having wavelengths longer (or shorter) than a reference wavelength and reflect the non-transmitted light. The reflective and transmissive characteristics of mirror 33 are shown in Figure 12.

The light wavelengths less than 700 nanometers which strike the coating on the front surface are reflected downward by an angle of 90° toward 35. The infrared portions 141 of the source beam 50 (wavelengths greater than 700 nanometers) are transmitted through mirror 33 and strike a beam block absorber shown schematically as 161. The beam block absorber 161 can be constructed of a black piece of aluminum (preferably with fins to radiate the heat, not shown) that absorbs the infrared wavelengths from the source beam 50 and re-emits the absorbed energy as heat, which can be carried away from the system and not introduced into the vital components which it might otherwise strike. Alternately, in place of a black piece of aluminum, other suitable means for absorbing infrared wavelengths may be utilized. Additionally, suitable means of separating or filtering the infrared component of the source beam 50 other than dichroic/thin film mirror 33 may be utilized. The remaining wavelengths of the source beam 50 resulting in a new source beam 55 are reflected from mirror 33 downward (as viewed in Figure 8) by an angle of 90° and strike the front surface of mirror 35. As with mirror 33, mirror 35 is formed as a wavelength filter so that the visible portion (430-700 nanometers in wavelength, see Figure 13A) of the source beam 55 resulting in a new source beam 57 is transmitted toward a polarizer cube 36 located in an optic path with mirror 35. The ultraviolet portion 37 of the source beam 55 (wavelengths less than 439 nanometers) is reflected by an angle of 90° toward the beam block absorber 161 on the left. (The characteristics of the mirrors 33 and 35 are outlined in Figures 12 & 13. Alternately, in place of dichroic/thin film mirror 35 and beam block absorber 161, other means for separating and absorbing the ultraviolet components of the source beam may be provided.

The source beam 57 is next directed toward a means for polarizing the source beam 57 into two orthogonally polarized beams. In the illustrative embodiment in Figure 8 of the invention, a polarizer cube 36 is utilized to separate the source beam 57 into a P-polarized beam 52 and an S-polarized beam 54. It should be further understood that when a polarizer cube is mentioned, that a polarizing plate or a piece of glass with a thin film polarizing coating deposited upon it, or a sandwich of glass, with the thin film polarizing layers deposed in between the glasses, can also be used for construction the system.

A suitable polarizer cube 36, in an illustrative embodiment of the invention, is known in the art as a birefringent polarizer. In particular, one useful for this application is called a MacNeille Polarizer and is described in Patent Nos. 2,403,731 and 2,449,287, with a general discussion having previously occurred above.

The polarizer 36, if constructed as a thin film Macneille polarizer, is sensitive to ultraviolet and infrared portions of the light spectrum because of the thin film coatings, thus the wavelength filtering by mirrors 33 and 35 that occurs before the beam enters the polarizer cube 36 is advantageous. This is because the ultraviolet light causes degradation of the internal coatings and the infrared light causes excessive heat buildup in the polarizer 36. The polarizer coatings start to absorb energy below 425 nanometer which will destroy their effectiveness. (see Figure 11 for wavelength response of a suitable polarizer cube 36) . The polarizer 36 polarizes the source beam 57 into two orthogonally polarized beams, beam 52 and beam 54, of equal areas but with different polarizations. The P-polarized beam 52 is propagated straight through to strike mirror 40 where it is deflected by a 90° angle toward the left. The other polarization component of the source beam cube 36, the S portion of the source beam, i.e., beam 54, is deflected left through a 90° angle from the diagonal of the polarizer cube 36. This S-polarized beam 54 is converted or changed into a P-polarization direction by a suitable polarization converter such as a half-wave polarization retarder 38, or, alternately, by reflections from coated mirrors 42, 44, and 46.

A general discussion of half wave retarder 38 requirements and specifications or reflections from mirrors 42, 44, 46 have been previously discussed above.

The half-wave retarder 38 thus produces a second

P-polarized beam 56. Second P-polarized beam 56 strikes mirror 42 and it is deflected by a 90° angle downward where it is deflected toward the left by mirrors 44 and 46. Mirrors 40, 42, 44 and 46 are front surfaced broadband mirrors that will maintain the P-polarization of the beam. Moreover, the reflective surfaces of these mirrors 40, 42, 44 and 46 can be generally rectangular in shape such that the beams reflected therefrom are also generally rectangular in shape. This allows a resultant unitary polarized beam to be formed with a generally rectangular outer peripheral configuration to match the light aperture of an LCD. The resultant unitary polarized beam 30 is thus doubled in its original size with the same rectangular area of the LCDs that it is going to strike and of one state of polarization, that is, a P-polarization.

Alternately, in place of the polarizer cube 36, any other suitable means for producing orthogonally polarized beams (52, 54) can be utilized. Additionally, means for converting (or changing) the polarization of one of the beams 54 other than the half-wave retarder 38 can be provided, such as reflection from coated mirrors 42, 44, 46. Moreover, other means than mirrors 40, 42, 44, 46 for combining the polarized beams 52 and 56 can be utilized. Finally the mirrors 40, 42, 44 and 46 can be placed in other arrangements for producing a resultant unitary polarized beam 30 having a shape that matches the rectangular peripheral shape of an LCD or LCD light aperture.

The rectangular polarized light 30 now encounters the coating surface of mirror 80 (which functions as a filtering means) where it is split into two beams 132, 134; beam 132 is deflected toward the top at an angle of 90° and beam 134 continues on through 80 to the left. Deflected beam 132, traveling toward the top, is separated by mirror 80 into a beam containing wavelengths between 600 nanometers and 700 nanometers (the red portion of the visible spectrum) cr.

2S alternately, other predetermined portions of the light spectrum, and of the P-polarization state. At this time, the red beam strikes mirror 82 which functions as a second filtering means. Figure 14 illustrates the reflectance characteristics of mirrors 80 and 82. As is apparent, these mirrors are selected to reflect the red portion of the visible spectrum and to allow wavelengths of less than 600 nanometers or, alternately, other predetermined portions of the light spectrum to pass through. Mirror 82 further filters the deflected red beam 132 so that it will match the CIE response needed for a good color balance (see Figures 10A & 10B) . As an example, the mirror curve (Figure 14) of mirror 82 can be shifted toward the right so that it will pass wavelengths below 615 nanometers or, alternately, other predetermined portions of the light spectrum and cause a deflected beam to appear deeper red to the human eye. Any "unwanted" wavelengths will pass through 82 and strike a red beam block 136 while the wanted wavelengths are deflected at an angle of 90° toward the left where they pass through a first LCD, which is termed as a red

LCD 138. Beam block 136 can be fabricated in the same manner as beam block absorber 161 previously described.

The red LCD 138 (as well as a green LCD 140 and a blue LCD 142 to follow) is of a type that can be caused to change its birefringence, thereby altering the orientation of the electric field vector of light passing through it, formed in a checkerboard arrangement with individual pixels 100 (see Figure 2A) . The red LCD 138 is driven by electronics in which each cell alters the respective light portion by rotating the vector of the electric field according to the image that is desired to be displayed (change by "twisting" or rotating the polarization state, see Figure 2A, by application of a voltage) . The resolution of the projected image will depend upon the number of cells in the LCD. A display of 320 horizontal pixels by 240 vertical pixels will yield a display of 76,800 pixels. A typical television set is 115,000 pixels. Thus, the deflected red beam 132, having now passed through the red LCD 138, is now an altered red beam 144 comprising a combination of polarizations for the individual pixels of a display, each pixel having a predetermined orientation of electric field vector by the driving electronics. As will hereinafter be more fully explained, the amount of the rotation in the polarization state for an individual pixel will eventually decide how much of the light for that pixel will be passed all the way through to finally strike the screen used for display. At this point, the altered red beam 144 strikes mirror 92 and is deflected at an angle of 90° upward toward the top. The purpose of mirror 92 is to combine the altered red beam 144 and altered green beam 152 (as viewed in Figure 8) . Mirror 92 thus functions as a combining means. The response curve for mirror 92 is shown in Figure 16. It is best that mirror 92 does not change the state of polarization of the altered red beam 144 or any other beam striking it (i.e. , altered green beam 152) . The deflected (from mirror 92) altered red beam 144 then continues on through mirror 90 which is constructed to pass any wavelengths greater than 515 nanometers (see Figure 17) or, alternately, other predetermined portions of the light spectrum. The purpose of mirror 90 is to combine the combined altered red 144 and altered green 152 beams with an altered blue beam 160. Mirror 90 thus also functions as a combining means. It is best that mirror 90 does not change the state of polarization (orientation of the electric field vector) of any beam impingent upon it.- The altered red beam 144 after passing through mirror 90 will continue on to a final polarizer called the polarizer analyzer 146. Polarizer analyzer 146 may also be a polarizer cube constructed as a MacNeille polarizer, or alternatively, as described above, on a single piece of glass or sandwiched between two pieces of glass. The vector component of the individual pixel light beams that is a P orientation of the electric field vector will pass through the polarizer analyzer 146 into a projection lens 148 and be projected as a part of beam 178 toward a screen (not shown in Figure 8) according to the magnification of the projection lens 148. The vector component of the altered red beam 144 that is not a P vector component (S-polarization) will be deflected by the polarizer analyzer 146 toward the left and be absorbed by beam block 150. See Figure IB for a pictorial illustration showing how a particular vector component is resolved into two components, each having a different orientation of the electric field vector. Beam block 150 may be fabricated in the same manner as beam block absorber 161 previously described. Thus, the intensity of the red light at the viewing surface is directly proportional to the amount of rotation of the altered red beam's electric field vector. Returning now to the single state of polarization rectangular light beam 30, it encounters the coating of mirrors 80 where it is split into two beams 132, 134. A red beam 132 is deflected toward the top 132 and the other beam, blue-green beam 134, passes through mirror 80 and continues on to the left. The blue-green beam 134 traveling through mirror 80 toward the left is a beam containing wavelengths between 415 nanometers and 600 nanometers (the blue-green portion of the visible spectrum) or, alternately, other predetermined portions of the light spectrum, and of the P-polarization state. The response curve for mirror 80 is shown in Figure 14. Next, the blue-green beam 134 strikes the surface coating of mirror 84 and the green portion 154 of the beam (500-600 nanometers or, alternately, other 5 predetermined portions of the light spectrum) is deflected by a 90° angle upward toward the green LCD 140, while the blue portion 156 of the _.beam (425-500 nanometers or, alternately, other predetermined portions of the light spectrum) continues on through mirror 84 o and toward mirror 86 at the left. Mirror 84 functions as a filtering means, and its response curve is shown in Figure 18.

The green beam 154 passes through the green LCD 140. Each cell alters its respective portion of the s green beam by rotating the orientation of the vector of the electric field according to the image that is desired to be displayed. Thus, the altered green beam 152, having now passed through the green LCD 140, is an altered green beam 152 comprising of a combination of 0 polarizations for the individual pixels of a display, each pixel having a predetermined orientation of electric field vector by the driving electronics. The amount of the rotation in the polarization state for an individual pixel will eventually decide how much of the 5 light for that pixel will be passed all the way through the polarizer analyzer 146 to finally strike the screen (not shown in Figure 8) used for display. At this point, the altered green beam 152 strikes mirror 92. As previously stated, the purpose of mirror 92 is to 0 combine the altered green beam 152 with the altered red beam 144 (see Figure 17) . The altered green beam 152 passes through mirror 92 and propagates upward. Mirror 92 does not change the state of polarization of the altered green beam 152 or any other beam (altered red 6 beam 144) striking it. The altered green beam 152 then continues on through mirror 90 because mirror 90 will pass any wavelength greater than 501 nanometers (see Figure 17) or, alternately, other predetermined portions of the 6 light spectrum. As previously stated, the purpose of mirror 90 is to combine the altered blue beam 160 (see Figure 16 tor response curve of mirror 92) . It is also preferable that mirror 90 does not change the state of polarization of any beam impingent upon or passing ιo through it.

After passing through mirror 90, the altered green beam 152 now continues on through the polarizer analyzer 146. Any portion of the light of the individual pixels of altered green beam 152 that is of a P-polarized ιe orientation will pass through the polarizer analyzer 146 into the projection lens 148 and be projected as part of beam 178 toward the screen (not shown) according to the magnification of the projection lens. The vector component of the altered green beam 152 that is not a P

20 vector component (S component) will be deflected by the polarizer analyzer 146 toward the left and be absorbed by the beam block 150. Thus, the intensity of the green light at the viewing surface is directly proportional to the amount of rotation of the green beam's electric

26 field vector. .

Returning now to the blue-green light beam striking the coating surface of mirror 84 where it is split into two beams 154, 156. A green beam 154 is deflected at an angle of 90° toward the top and a blue beam 156

30 continues through mirror 84 to the left. The blue beam 156 traveling through 84 toward the left is a beam containing wavelengths between 415 nanometers and 500 nanometers (the blue portion of the visible spectrum) or, alternately, other predetermined portions of the

35 light spectrum, of the P-polarization state. The blue beam 156 continues on toward the left and strikes the surface coating of mirror 86 (mirror 86 may be a front surface broadband mirror; however, it must retain the P state of polarization for the blue beam) and the blue beam (415-500 nanometers or, alternately, other predetermined portions of the light spectrum) is deflected at an angle of 90° upward toward the mirror 88. A wave response for mirror 84 is shown in Ficfure 15. At this time, the reflected blue beam 156 from mirror 86 strikes mirror 88 for further filtering. Further filtering can be done by mirror 88 on the blue beam 156 so that it will match the CIE response needed for a good color balance (see Figures 10 A, 10B) . For instance, mirror 88 can be constructed with a mirror curve as shown in Figure 18 which is shifted toward the left so that it will transmit wavelengths above 495 nanometers or, alternately, other predetermined portions of the light spectrum, and cause the beam to appear deeper blue to the human eye. Any "unwanted" wavelengths will pass through mirror 88 and strike a blue beam block 158 while the wanted wavelengths are deflected at an angle of 90° toward the right where they pass through the blue LCD 142. Blue beam block 158 may be constructed in the same manner as beam block absorber 161 previously described. As before, it is important that mirror 88 does not change the state of polarization of the blue beam 156. The blue portion of the blue beam 156 passes through the blue LCD 142. Each cell alters the respective light portion by rotating the vector of the electric field according to the image that is desired to be displayed. Thus, an altered blue beam 160, having now passed through the blue LCD 142, is now an altered blue beam comprising a combination of polarizations for the individual pixels of a display, each pixel having a predetermined- orientation of electric field vector by the driving electronics. The amount of the rotation in the polarization state for an individual pixel will eventually decide how much of the light for that pixel passes all the way through to finally strike the screen (not shown in Figure 8) used for display. At this point, the altered islue beam 160 strikes mirror 90 and is reflected upward at an angle of 90° toward the top (as viewed in Figure 8) for combining with altered red beam 144 and altered green beam 152. Mirror 90 will allow any wavelengths less than 500 nanometers, to be reflected (see Figure 17) or, alternately, other predetermined portions of the light spectrum. It is important that mirror 90 does not change the state of polarization of the altered blue beam 160, or any other beam striking it. The altered blue beam 160 now continues on to the polarizer analyzer 146. The vector component of the individual pixel light beams that is of a P-polarized component will pass through the polarizer analyzer 146 into the projection lens 148 and be projected as a part of beam 178 toward the screen according to the magnification of the projection lens. The vector component of the altered blue beam 160 that is not a P vector component (S vector component) will be deflected by the polarizer analyzer 146 toward the left and be absorbed by the beam block 150. Beam block 150 can be fabricated in the same manner as beam block absorber 161 previously described. Thus, the intensity of the blue light at the viewing surface is directly proportional to the amount of rotation of the blue beam's electric field vector. ■

At this point, all of the colors of the display (red, green and blue) have passed through the system and the projection lens 148 to be projected 178 onto the screen (not shown in Figure 8) . They are combined on top of each other to produce a pixelized image that has the correct color balance.

The projection lens 148 is either a single lens or a combination of lenses that produces a good focused image on the screen. It has a back focal point of the distance equal to the distance from the rear of the lens to each one of the LCDs 138, 140, 142 in the system. This distance is made the same for all of the three LCDs. Thus, to focus and align the system, it is necessary to first project one of the individual colors without the others. When this is done and the image is focused, then the second color is projected along with the first color and the second color LCD is moved spatially to produce a sharp image or pixel on top of the first color pixel. The entire image of the second color is then aligned to the image of the first color to make a perfect match with regard to size, focus and alignment. Next, the second color is then turned off or blocked and then the third color is projected along with the first color and the third color LCD is moved spatially to produce a sharp image or pixel on top of the first color pixel. The entire image of the third color is then aligned to the image_of the first color to make a perfect match with regard to size, focus and alignment.

The image is then projected as beam 178 with all colors turned on and a final adjustment can then be made at this time.

The selection of the wavelengths applicable to mirrors 82 and 88 can be judicially applied so that the color balances of different lamps can be adjusted for color balance of the final output without the redesign of the entire optical system (see Figures 10A & 10B) . Referring to Figure 8A, a functional description of Figure 8 is shown with the same parts, but with the part numbers removed for clarity. The parts are grouped according to functionality, however other parts can be 5 substituted, removed, or added according to what is needed to be achieved. Figure 8A is meant as an illustrative description of the nomenclature used in the claims.

In Figures 8 & 8A the light source 32, the o reflector 41, the collimating lens 43, mirror 33, mirror 35 and beam stop 161 work in accordance together, as detailed in the description of Figure 8 above, for producing a beam of light 57 for the projector described. 6 The resolving of the light beam 57 is accomplished when it is sent through the polarizing means 36, as detailed in the description of Figure 8 above, and resolved into two orthogonally polarized light beams 52, 54. The resolving can also include a half wave retarder 0 38 for producing light beam 56 which is of the same polarization as that of light beam 52.

The forming of the light beam 30 occurs when the two light beams are respectively reflected from forming means 40, 42, 44, and 46, as detailed in the description & for Figures 3, 3A, 3B & 3C above, into a single beam of light 30 as depicted in Figure 5. Arrangements of the forming means 40, 44, 46 other than those shown in Fic urea 3, 3A & 3C are also possible. The arrangement of forming means in Figures 3A & 3B are the same. o Moreover, the forming means 40, 44, 46 may be shaped and arranged to produce a rectangular or square shaped beam, or any other desired geometrical shape.

The separating of the beam, as described above for Figure 8, includes the separating means 80, 84, 86. The 5 formed polarized light beam 30 encounters the separating means 80 where it is separated into two beams 132, 134. Deflected beam 132 travels toward the top. The beam 134 strikes separating means 84 where it is separated into two beams 154, 156. Deflected beam 154 travels toward the top. The beam 156 strikes separating means 86 where deflected beam 154 travels toward the top.

Altering of the separate beams consists of the LCDs 138, 140, 142 or other suitable altering means, as described above for Figure 8. Each beam passes through its respective LCD. Each cell alters its respective portion of a beam by rotating the orientation of the vector of the electric field according to the image that is desired to be displayed. Thus, an altered beam, having now passed through the LCD, is an altered beam comprising of a combination of polarizations for the individual pixels of a display, each pixel having a predetermined orientation of electric field vector by the driving electronics. The amount of the rotation in the polarization state for an individual pixel will eventually decide how much of the light for that pixel will be passed all the way through the polarizing means 146 to finally strike the screen (not shown in Figure 8A) used for display.

The adjusting of the beams 132, 156 is accomplished by the adjusting means 82, 88 and the beam stops 136, 158. Any "unwanted" wavelengths will pass through 82, 88 and strike beam block 136, 158 while the wanted wavelengths are deflected at an angle of 90° toward the respective LCD. Beam block 136, 158 can be fabricated in the same manner as beam block absorber 161 previously described above, as detailed in the description of Figure 8 above.

The combining of the beams 144, 152, & 160 is accomplished by the combining means 90, 92. However, these combining means can also be used for adjusting if so desired by their beam pass/reflection criteria. The altered beam 134 travels through combining means 92, while altered beam 144 is deflected from combining means 92, which serves to combine the two beams 144, 152 into a single beam. It is preferable that combining means 92 does not change the state of polarization of any beam impingent upon or passing through it. This combined beam travels through reflecting means 90. It is preferable that combining means 90 does not change the state of polarization of any beam impingent upon or passing through it. The purpose of combining means 90 is to combine the combined altered 144 and altered 152 beams with an altered beam 160 into a single combined altered beam, as detailed in the description of Figure 8 above.

After the beams have been combined into a single beam they are directed toward the resolving means where they are separated into two beams by the polarizing beam splitter means 146, with the desired separate beam being passed to the projecting means 148, as detailed in the description of Figure 8 above.

The projecting means 148 can be either a single lens or a combination of lenses that produces a good focused image on the screen. It has a back focal point of the distance equal to the distance from the rear of the lens to each one of the altering means 138, 140, 142 in the system. This distance is made the same for all of the three altering means.

While the description above has been particularly shown and described with reference to preferred embodiments thereof, it will be understood by those skilled in the art that various changes in form and details can be made without departing from the spirit and scope of this invention. By way of example and not limitation, a system and method constructed in accordance with the invention offers the following results and advantages over prior art illumination systems for a LCLV projector. 6 A rectangular singular polarized beam is created that will efficiently fill the aperture of an LCD display thus maximizing the output of light from an LCD projector.

The divergence of the resultant beam at the LCD 0 display is smaller than with other methods of combination, i.e. , U.S. Patent No. 4,913,529.

The system of the invention enables projectors to utilize brighter light sources for projection, thus enabling the person viewing the projection to see the s projection source in higher ambient light levels.

With the system of the invention, projectors will be brighter and lighter.

With the system of the invention, projectors will consume less energy due to the more efficient light o source.

With the system of the invention, television projected on the larger screen video will be easier to watch.

The present invention can be used in a color LCLV 5 projector that utilizes all the available visible light

(considering the geometry of the light source) generated by the light source. This allows the highest possible brightness at the screen for a given size light source.

In addition, heat generating non-visible components of 0 the light source spectrum (i.e. , infrared and ultraviolet) are removed from the source beam prior to polarization

(orientation of the electric field vector) so that excessive heat is not generated in the system. This

.allows the optical components to operate at a 5 temperature only slightly greater than ambient temperature, i.e. , in the range of ambient temperature plus 5° to 10°F. Moreover, the system of the invention has a minimum number of components that can be easily adjusted to achieve a projected image of high brightness, resolution and contrast. As a result, this permits the construction of smaller, more compact projectors using smaller light sources, which in itself results in longer life for the components, including the light sources, and the invention avoids the problem of feeding the rejected light back into the light source, thus heating the light source and causing shortened life times of the luminiferous device.

Thus, the invention provides a color liquid crystal light valve LCD projector that produces an image of high brightness, contrast and resolution. Additionally, harmful infrared and ultraviolet rays have been removed from the projected image. Moreover, in light of the herein described invention, components of the system can be modified or easily adjusted to produce a color enhanced image.

While the invention has been particularly shown and described with reference to preferred embodiments thereof, it will be understood by those skilled in the art that various_^ changes in form and details can be made without departing from the spirit and scope of this invention.

Claims

What is claimed is:

1. A method of reflecting a predetermined range of wavelengths of a beam of light while transmitting the remaining range of wavelengths of the . beam of light without changing the orientation of electric field vector for the reflected and transmitted ranges of wavelengths, comprising:

[a] selecting a predetermined range of wavelengths of a beam of light to be reflected;

[b] selecting an element formed from a material which is transparent to the range of wavelengths of the light beam to be reflected and transmitted and having a predetermined refractive index;

[c] selecting a coating comprised of one or more layers of predetermined dielectric materials for reflecting a predetermined range of wavelengths of the beam of light without changing the orientation of electric field vector for the reflected range of wavelengths while transmitting through the coating the remaining range of wavelengths of the beam of light without changing the orientation of electric field vector of the transmitted ranges of wavelengths, each layer of the coating having a predetermined refractive index;

[d] forming the coating on the element with the first layer being disposed in contacting engagement with at least a portion of the element;

[ej directing a beam of light toward the coated element at a predetermined angle of incidence; and [f] using the coating on the coated element to reflect the predetermined range of wavelengths while transmitting the remaining range of wavelengths of the beam of light without changing the orientation of electric field vector of the reflected and transmitted ranges of wavelengths.

2. A method as described in Claim 1 in which step [c] further includes selecting a coating comprised of one or more layers of predetermined dielectric materials in which the first layer of the coating has a refractive index substantially equal to the refractive index of the element.

3. A method as described in Claim 1 in which step [c] further includes selecting a coating comprised of one or more layers of predetermined dielectric materials in which the first layer of the coating has a refractive index that is not substantially equal to the refractive index of the element.

4. A method as described in Claim 1 in which step [e] further includes directing a beam of light toward the coated element at a predetermined angle of incidence varying between approximately 30° and 60°.

5. A method as described in Claim 1 in which the step le] further includes directing a beam of light toward the coated element at a predetermined angle of incidence varying between approximately 40° and 50°.

6. A method as described in Claim 1 in which step [e] further includes directing a beam of light toward the coated element at a predetermined angle of incidence equaling approximately 45°.

7. A method as described in Claim 1 in which step [el further includes directing a beam of light to strike

^• first the coating.

8. A method as described in Claim 1 in which step [e] further includes directing a beam of light to first strike the element.

9. A filter means comprising an element and a coating, the element being formed from a material which is transparent to the ranges of wavelengths to be reflected and transmitted and having a predetermined refractive index, the coating comprising one or more layers of materials, each layer of material having a predetermined refractive index for reflecting a predetermined range of wavelengths of the beam of light without changing the orientation of electric field vector for the reflected range of wavelengths while transmitting the remaining range of wavelengths of the beam of light without changing the orientation of the electric field vector thereof, the coating including a first layer which is disposed in contacting engagement with the element.

10. A filter means as described in Claim 9 in which the first layer has a refractive index substantially equal to the refractive index of the element.

11. A filter means as described in Claim 9 in which the first layer has a refractive index that is not substantially equal to the refractive index of the element.

12. A method of reflecting each of two or more predetermined ranges of wavelengths of a beam of light from a respective one of two coated elements while transmitting the remaining portion of each unreflected range of wavelengths of the beam of light through the respective coated elements without changing the orientation of electric field vector of the reflected and transmitted ranges of wavelengths, comprising:

[a] selecting first and second predetermined ranges of wavelengths of a beam of light to be reflected;

[b] selecting first and second elements, each of the elements being formed from a material which is transparent to the respective ranges of wavelengths of the light beam to be reflected and transmitted, each of the elements having a predetermined refractive index;

Ic] selecting a coating for each of the elements for reflecting a respective one of the first and second predetermined ranges of wavelengths of the beam of light while transmitting through the respective coating the remaining range of wavelengths of the beam of light without changing the orientation of electric field vector of the respective reflected and transmitted ranges of wavelengths, each coating having one or more layers of predetermined dielectric materials, each layer having a predetermined refractive index;

[d] ^• forming on each of the elements a respective one of the coatings the elements with the first layer of each coating being disposed in contacting engagement with at least a portion of the elements on which it is formed;

[e] directing a beam of light toward each of the coated elements at a predetermined angle of incidence; and [f] using the coating on the coated elements to reflect a respective one of a predetermined ranges of wavelengths while transmitting the remaining range of wavelengths of the beam of light without changing the orientation of electric field vector of the reflected and transmitted ranges of wavelengths.

13. A method as described in Claim 12 in which step [e] further includes directing a beam of light to strike first of the coating formed on the first and second elements.

14. A method as described in Claim 12 in which step [e] further includes directing a beam of light to strike first the elements.

15. A method as described in Claim 12 in which step [e] further includes directing a beam of light toward the coated element at a predetermined angle of incidence varying between 30° and 60°.

16. A method as described in Claim 12 in which step [e] further includes directing a beam of light toward the coated element at a predetermined angle of incidence varying between 40° and 50°.

17. A method as described in Claim 12 in which step [e] further includes directing a beam of light toward the coated element at a predetermined angle of incidence equaling approximately 45°.

18. A method of reflecting a predetermined range of wavelengths of a beam of light while changing the orientation of electric field vector of the reflected range of wavelength by a predetermined amount, comprising:

[b] selecting an element formed from a material and having a predetermined refractive index; [cl selecting a coating comprised of one or more layers of predetermined dielectric materials for reflecting a predetermined range of wavelengths of the beam of light while changing the orientation of electric field vector of the reflected range of wavelengths by a predetermined amount, each layer having a predetermined refractive index;

[d] forming the coating on the element, with the first layer being disposed in contacting engagement with at least a portion of the element;

[e] directing a beam of light toward the coating;

[f] directing a beam of light toward the coated element at a predetermined angle of incidence; and

[g] using the coating to reflect a predetermined range of wavelengths while changing the orientation of electric field vector of the reflected range of wavelengths by a predetermined amount.

19. A method as described in Claim 18 in which step [e] includes directing a beam of light to strike first the coating.

20. A method as described in Claim 18 in which step [e] further includes directing a beam of light to strike the first the element.

21. A method as described in Claim 18 in which step [c] further includes selecting a coating comprised of one or more layers of predetermined dielectric materials in which the first layer of the coating has a refractive index substantially equal to the refractive index of the element.

22. A method as described in Claim 18 in which step [c] further includes selecting a coating comprised of one or more layers of predetermined dielectric materials in which the first layer of the coating has a refractive index that is not substantially equal to the refractive index of the element.

23. A method as described in Claim 18 in which step [f] further includes directing a beam of light toward the coated element at a predetermined angle of incidence varying between approximately 30° and 60°.

24. A method as described in Claim 18 in which step [f] further directing a beam of light toward the element includes directing a beam of light toward the coated element at a predetermined angle of incidence varying between approximately 40° and 50°.

25. A method as described in Claim 18 in which step [f] further directing a beam of light toward the element includes directing a beam of light toward the coated element at a predetermined angle of incidence equaling approximately 45°.

26. A mirror means formed from an element and a dielectric coating, the element being formed from a transparent material and having a predetermined refractive index, the coating comprising one or more layers of dielectric materials, each layer of material having a predetermined refractive index for reflecting a predetermined range of wavelengths of the beam of light while changing the orientation of the electric field vector for the reflected range of wavelengths by a predetermined amount, the first layer of the coating being disposed in contacting engagement with the element.

27. A mirror means as described in Claim 27 in which the first layer has a refractive index substantially equal to the refractive index of the element.

28. A mirror means as described in Claim 27 in which the first layer of the coating has a refractive index that is not substantially equal to the refractive index of the element.

29. A method of reflecting each of two or more predetermined ranges of wavelengths of a beam of light from a respective one of two coated elements while changing the orientation of electric field vector of the reflected ranges of wavelengths, comprising:

[a] selecting a first and second predetermined ranges of wavelengths of a beam of light to be reflected;

[b] selecting first and second elements, each of the elements being formed from a transparent material, each of the elements having a predetermined refractive index;

[c] selecting a coating for each of the elements for reflecting a respective one of the first and second predetermined ranges of wavelengths of the beam of light while changing the orientation of electric field vector of the reflected ranges of wavelengths by a predetermined amount, each layer having a predetermined refractive index;

[d] forming each of the coatings on a respective one of the elements with the first layer of each coating being disposed in contacting engagement with at least a portion of the respective one of the elements on which same is coated; [e] directing a beam of light toward each of the coated elements at a predetermined angle of incidence varying between approximately 30° and 60°; and

[f] using the coated elements to reflect a respective one of the predetermined ranges of wavelengths while changing the orientation of electric field vector of the reflected ranges of wavelengths.

30. A method as described in Claim 29 in which step [e] further includes directing a beam of light to strike first the coatings formed on the first and second elements.

31. A method as described in Claim 29 in which step [e] further includes directing a beam of light to strike first the elements.

32. A method as described in Claim 29 in which step [e] further includes directing a beam of light toward the coated elements at a predetermined angle of incidence varying between 30° and 60°.

33. A method as described in Claim 29 in which step [e] further includes directing a beam of light toward the coated elements at a predetermined angle of incidence varying between 40° and 50°.

34. A method as described in Claim 29 in which step [e] further includes directing a beam of light toward the coated elements at a predetermined angle of incidence equaling approximately 45°.