The present invention generally relates to display illumination and more particularly relates to a backlight unit employing a reflective polarizer based on formed birefringence for use with light having a large incident angle.
Liquid Crystal Displays (LCDs) are widely used in a broad range of display devices and compete favorably with the more conventional cathode-ray tube (CRT) monitor for numerous display applications. While direct-view LCDs continually improve in resolution, speed, and overall performance, however, display brightness can still be disappointing when compared against CRTs. This shortcoming is particularly noticeable over larger viewing angles.
An inherent problem with LCD displays that limits brightness relates to polarization dependence. In typical applications, the LCD device itself has a pair of absorptive polarizers that absorb half of the unpolarized light emitted from the light source. Thus, even where brighter light sources can be provided, a considerable portion of this light is still discarded.
One solution to this problem has been to use a reflective polarizer, such as Vikuiti™ Dual Brightness Enhancement Film, manufactured by 3M, St. Paul, Minn. or wire grid polarizer wire-grid polarizer available from Moxtek, Inc., Orem, Utah. These devices transmit only the light having the desired polarization for the LCD and reflect light of the orthogonal polarization, which can be re-oriented by illumination components so that it is eventually used.
Reflective polarizers work well for a portion of the light, particularly for light at incident angles near normal with respect to the reflective polarizer. However, light incident at angles diverging from normal, or large-angle light, is not used efficiently. This inefficiency can be difficult to remedy, since some deliberate scattering of light is typically performed within the light guide plate (LGP). Scattering elements, such as printed dots or an etched pattern, are often necessary for uniformizing the light in a conventional backlight system. Thus, uniformization and polarization elements may tend to work at cross-purposes, requiring some compromise to achieve both suitable brightness and acceptable uniformity.
One approach using a reflective polarizer, or polarizing beamsplitter, positions this polarizing component at the bottom face of a light guide plate without any scattering element, as disclosed in U.S. Pat. No. 6,285,423 to Li et al. (see '423 Li et al. FIG. 1a, numeral 20). With this type of arrangement, light transmitted through the reflective polarizer is redirected as illumination output at near normal angles. Light reflected by the reflective polarizer is directed to a polarization converter for changing the polarization of at least a portion of this light and redirecting it for eventual output.
An alternate approach using a reflective polarizer positions this element at the top of a light guide plate without any scattering element, as disclosed in U.S. Pat. No. 6,443,585 to Saccomanno (see '585 Saccomanno FIG. 1 numeral 8). This approach generally provides higher light extraction efficiency due to reduced loss in scattering, but it does not provide a satisfactory polarizing effect.
In order to understand the problems with reflective polarizer use encountered with both the Li et al. '423 and Saccomanno '585 approaches, it is useful to observe how polarized light is handled within the light guide plate of an illumination system. To do this, compare the schematic view of
A detailed description of a conventional reflective polarizer 20 can be found in the Li et al. U.S. Pat. No. 6,285,423 disclosure. Briefly, according to conventional practice, reflective polarizer 20 can have a number of possible forms, including: (1) a stack of 1.38/2.35 dielectric layers deposited on polycarbonate substrates; (2) a stack of metal/dielectric layers on a substrate; (3) a layer of birefringent material such as liquid crystalline material sandwiched between two substrates; or (4) a stretched plastic film with a blend of birefringent material and isotropic material, as shown in FIGS. 8c, 10c, and 12c of U.S. Pat. No. 6,285,423. However, it must be emphasized that the polarizing effect is achieved only when the light is within the limited acceptance angle range of the device. According to configurations shown in the Li et al. '423 disclosure, the acceptance angle (referred to as the incident angle in the Li et al. '423 patent) is either in the range 69° to 79° (see Li et al. '423 patent, FIG. 9); 62° to 82° (see Li et al. '423 patent, FIG. 11); or 70° to 84° (see Li et al. '423 patent, FIG. 13).
When the following condition is met for angle θTIR, the reflective polarizer transmits one polarization and reflects the other polarization due to total internal reflection (TIR), thus separating two polarization states for all light trapped in the light guide plate:
where nLGP is the index of refraction of the light guide plate substrate, no is the extraordinary index of refraction, ne is the ordinary index of refraction.
For a better understanding of the limitations on light incident angle inherent to the conventional approach used in the Li et al. '423 disclosure, it is particularly instructive to take a closer look at the case when reflective polarizer 20 is a layer of birefringent material with extraordinary index ne and ordinary index no. In this particular case, the direction of ne is parallel to the light source 14 or perpendicular to the plane of incidence shown in
The light trapped in the light guide has an acceptance angle θa, which is bounded as follows:
that is, for a substrate with index nLGP=1.589:
51°≦θa<90°.
Thus, light between 51 and 90 degrees is within the acceptance angle for the light guide.
However, a good polarization separation is provided only where there is total internal reflection, that is, only for light with incident angle greater than
With a conventional light guide plate, this lower threshold is at 71° for no=1.5 and nLGP=1.589. This means that, according to the teaching disclosed in the Li et al. '423 patent, reflective polarizer 20 does not provide satisfactory polarization separation effect for light with incident angles between 51° and 71°. Only for light that is in the 71-90 degree range is acceptable polarization separation provided.
Table 1 and the comparative examples of accompanying
In Table 1, exemplary values are given for indices nLGP, ne, and no. The depth D is the thickness of the birefringent polarization material. Of particular interest for overall performance is the overlap angle range and effective acceptance angle θa range given in the right-most columns.
It is to be noted that the 89 degree value shown in tables and used in description in the present disclosure is used to express an angular value for acceptance angle θa that can approach 90 degrees as a limit, but is less than 90 degrees.
For the example of
The example of
As the comparative examples of
However, materials with large birefringence and other desired properties are not easily available, may not be usable for reflective polarizer use, or may not even exist. Light guide plate 12 must have an index of refraction nLGP that is substantially equal to the larger of the extraordinary index ne and ordinary index no. The smaller of the extraordinary index ne and ordinary index no is usually greater than 1.50, which means that the light guide plate must have relatively large index of refraction nLGP, for example, that of polycarbonate, 1.589. However, this is undesirable or unworkable, because the most commonly used light guide plate is made of poly(methyl methacrylate) (PMMA) with index of refraction of around 1.49. Thus, solutions using high levels of birefringence are constrained by properties of the dielectric materials themselves.
Clearly, a good portion of the light incident from light source 14 (
The invention provides a backlight unit comprising in order:
(1) a light source;
(2) a light guide plate (LGP) having an incident face toward the light source and having a refractive index nLGP;
(3) a reflective polarizer having formed birefringence in optical contact with the LGP including a layer having:
(i) the cross-sectional dimensions of the first and second materials, in a plane parallel to the light incident face of the LGP, are smaller than 100 nm in their width dimensions; and
(ii) the parameters of the reflective polarizer are selected to provide R0>0.8 for one polarization state and T90>0.8 for the orthogonal polarization state, for light of wavelength of 550 nm, for least one reflective polarizer angle of light incidence θa.
It is a feature of the present invention that it uses formed birefringence to obtain high levels of polarization separation using conventionally available materials.
It is an advantage of the present invention that it provides a reflective polarizer for an illumination apparatus that can exhibit the needed level of polarization separation for use with a light guiding plate in a number of display applications.
These and other aspects, objects, features and advantages of the present invention will be more clearly understood and appreciated from a review of the following detailed description of the preferred embodiments and appended claims, and by reference to the accompanying drawings.
While the specification concludes with claims particularly pointing out and distinctly claiming the subject matter of the present invention, it is believed that the invention will be better understood from the following description when taken in conjunction with the accompanying drawings, wherein:
The present description is directed in particular to elements forming part of, or cooperating more directly with, apparatus in accordance with the invention. It is to be understood that elements not specifically shown or described may take various forms well known to those skilled in the art.
Figures showing the structure and arrangement of the reflective polarizer of the present invention are not drawn with attention to scale, but are provided to show overall structure, composition, and function.
The present invention addresses the problem of angular limitation for polarizing light within the light guide plate by using a novel application of formed birefringence. Formed birefringence, also termed form birefringence, uses devices having generally periodic structures with features and spacing, or pitch dimensions, smaller than a wavelength. The formed birefringence principle is used, for example, in wire grid polarizers that use a grating of conductive wires having sufficiently high spatial frequency that zero order light is no longer diffracted and optical path lengths parallel and perpendicular to the grating features are distinct. One example of a wire-grid polarizer is given in U.S. Pat. No. 6,788,461 entitled “Wire Grid Polarizer” to Kurtz et al. These conventional solutions employ conductive metal wires or elongated metal layers for polarization. While such devices are capable of providing good separation of polarization states, however, their use of metal materials has unwanted side effects due to some inherent amount of light absorption.
In the present invention, however, instead of using reflective and conductive wires, a layer is formed comprising two dielectric, non-conductive materials, extended in length along the general direction of light propagation, one with a high index of refraction n1 and the other with a low index of refraction n2. The two dielectric materials can be isotropic or birefringent. For illustration purposes, all the examples given in this disclosure assume that the two dielectric materials are isotropic, that is, that each material has only one index of refraction. The resulting reflective polarizer of the present invention is structured in such a way that formed birefringence is effected by this arrangement, so that the layer is approximately equivalent in behavior to a layer of highly birefringent material with effective extraordinary index ne and ordinary index no. Here, the effective extraordinary index ne and ordinary index no that are obtained as a result of the formed birefringent structure are typically different from the indices n1 and n2 of the original materials. The formed birefringence of this structure is always calculated as a negative number, i.e., Δn=ne−no<0. In practice, however, since the difference is the quantity of interest, the absolute value |Δn| can be used to quantify birefringence. As a comparison, one or both of n1 and n2 are typically complex numbers for conductive materials, so that the formed birefringence is also a complex number. This arrangement implies some inherent amount of absorption when using conductive materials.
The reflective polarizer according to this invention has three important advantages that are of particular value for display applications. First, the device provides a high level of birefringence |Δn| in a range of 0.2-0.5 or greater, well above the birefringence obtained by conventional reflective polarizers that use a single birefringent material. This is made possible with two isotropic materials, one with a low index of refraction n2, as low as 1.0 (air), and, the other, a high index of refraction n1 as large as 1.6-1.8 (with some plastics), and even as large as 2.35 (using inorganic materials such as TiO2.) Second, the effective ordinary index no can be adjusted to a low value. Thus, it is possible to use an LGP substrate with low index of refraction that satisfies no=nLGP>ne, where nLGP is the refractive index of the LGP substrate, an important relationship for reflective polarizer use with backlighting apparatus, as noted earlier. Third, this reflective polarizer has little absorption due to the fact that both n1 and n2 are real numbers for dielectric, non-conductive materials. As noted earlier, this is in contrast to the conventional conductive wire grid polarizer that exhibits some intrinsic absorption.
The perspective view of
Reflective polarizer 50 is in optical contact with light guide plate 12. Optical contact, as the term is used in the present disclosure, is equivalent to physical contact or, optionally, to coupling through an optical adhesive. There is no air gap between reflective polarizer 50 and light guide plate 12.
Reflective polarizer 50 has a number of elongated channels 31 and 32, extended in a length direction that is generally perpendicular to incident face 16 and distributed widthwise in an alternating pattern. The channels are generally perpendicular if at 90° to the incident face or within ±15 degrees. Each channel 31, 32 is formed using a non-conductive or dielectric optical material. As shown in
In a comparative example, consider channels 31 and 32 extending in a direction orthogonal to the direction shown in
w1, w2: cross-sectional widths for channels 31 and 32, respectively;
P: pitch for channels 31 and 32, here equal to (w1+w2);
d: depth for channels 31 and 32.
One important dimensional relationship is the fill factor f1, or duty cycle, which can be stated as follows:
f1=W1/P
In the context of the present disclosure, pitch P is intended to include average pitch, where there may be some variation in pitch as a result of fabrication.
For the formed birefringence embodiments of
no0=√{square root over (f1n12+(1−f1)n22)}
ne0=n12n22√{square root over ((1−f1)n12+f1n22)},
Alternately, the second-order effective medium theory can be used, with the following computations:
In general, the zero-order value is best applied where the pitch P is very small relative to the wavelengths of incident light, so that:
Where pitch
is not negligible, the second order equations are likely to be more accurate.
In
In
In summary, it can be seen from
Reference dashed box Q shown in
Analyses were modeled at 550 nm using the Gsolver grating analysis software tool, which allows sub-wavelength structures to be thoroughly modeled using rigorous coupled wave analysis (RCWA). Gsolver software is commercially available from Grating Solver Development Company, P.O. Box 353, Allen, Tex.
Examples for Polycarbonate Substrate (
Turning to the example of
For light polarized in a plane parallel to channels 31 and 32, the light encounters effective ordinary index no and LGP 12 substrate index nLGP. The transmission vs. acceptance angle behavior is described by curve T90 (filled squares). Because the absorption of the material is small and assumed to approximate zero, the reflection R90=1−T90 and is not plotted. As shown within dashed box Q, the transmission value T90 is greater than 88% for the full range of desired acceptance angles, indicating that light of this polarization is substantially transmitted through the reflective polarizer.
For light polarized in a plane perpendicular to channels 31, 32, effective extraordinary index ne and substrate index nLGP apply. The reflection vs. acceptance angle characteristic is described by curves R0 (empty triangles). Again, the transmission T0=1−R0 is not plotted. R0 is greater than 90% for all incident angles above 58°, indicating that light of this polarization is reflected from the reflective polarizer. R0 exceeds the threshold of 80% for 51°≦θa<90°, indicating that this reflective polarizer functions well for essentially all the light coupled into the light guide plate.
Given the performance shown in
Table 2 that follows gives a summary of parameters and performance values that apply for
Example 1, described with reference to the curves of
Example 2, shown in
Example 3, shown in
Example 4, shown in
Example 5, shown in
Example 6, shown in
Examples for PMMA Substrate (
The examples of
Referring first to
In the example of
The example of
The example of
The examples given in
Fabrication
Any of a number of different fabrication techniques could be used for forming reflective polarizer 50. For an embodiment using air in channels 32, the channel structure can be directly patterned into the substrate that will form channels 31 using standard photolithography. Other methods could use deposition of material 31 onto the substrate using inkjet printing or other precision deposition techniques.
In an alternate method using photolithography, a metal layer could be applied as a mask for subsequent etching. Here, a metal layer is deposited, using a metal such as aluminum. The deposition method can be one of several standard methods including thermal evaporation or sputtering. Next the metal is patterned using standard photolithography followed by a metal etch (possibly dry metal etch such as CC14, BC13) to form a mask pattern. Channels 32 can then be etched to remove unwanted material, leaving the desired void for air.
Alternatively, methods including repeatedly etching the dielectric or ion beam milling could be employed. Lift off methods can also be used. Wet etch using etch compounds such as HF for a SiO2 etch could be used.
In other embodiments, multiple layers of dielectric materials could be deposited to form either or both channels 31 and 32. This type of fabrication would require repeated processes of deposition and etching until the proper depth d (
Referring back to the embodiment shown in
Reflective polarizer 50 of the present invention can be used for display backplane illumination in a number of different possible embodiments. Referring to
Reflective polarizer 50 can be combined with light guide plate 12 in a number of different possible configurations.
Turning first to the illustrative example of
Similarly, in
By comparison against conventional reflective polarizer solutions such as those described in the background section given earlier, the reflective polarizer of the present invention provides improved polarization separation over the broad range of angles of light within the light guide plate. By using formed birefringence, the reflective polarizer of the present invention provides a high degree of polarization separation in a compact, low-cost component.
The entire contents of the patents and other publications referred to in this specification are incorporated herein by reference. The invention has been described in detail with particular reference to certain preferred embodiments thereof, but it will be understood that variations and modifications can be effected within the spirit and scope of the invention.
Number | Name | Date | Kind |
---|---|---|---|
6285423 | Li et al. | Sep 2001 | B1 |
6443585 | Saccomanno | Sep 2002 | B1 |
6788461 | Kurtz et al. | Sep 2004 | B2 |
6798468 | Iijima | Sep 2004 | B1 |
Number | Date | Country | |
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20080304282 A1 | Dec 2008 | US |