Optical film for the reduction of optical artifacts

What is claimed: 1 . An optical film for reducing at least one of sparkle and moire in a display system, the optical film comprising a structured first major surface that in at least a first cross-section in a first plane substantially orthogonal to the optical film has a sinusoidal shape having a variable pitch of greater than about 0.5 microns, such that for a substantially normally incident light and blue, green, and red wavelengths that are at least 50 nm apart from each other and are disposed within respective blue, green and red wavelength ranges extending respectively from about 420 nm to about 480 nm, about 490 nm to about 560 nm, and about 590 nm to about 670 nm, optical transmissions of the optical film versus transmitted angle for the blue, green and red wavelengths comprise respective blue, green, and red transmission bands disposed at angles greater than about 1 degree and having respective blue, green, and red full width at half maxima (FWHMs), at least two of which at least partially overlap. 2 . The optical film of claim 1 , wherein the variable pitch is substantially random. 3 . The optical film of claim 1 , wherein the sinusoidal shape of the structured first major surface in the first cross-section comprises a repeating pattern of a same group of N first sinusoid structures, such that N≥2. 4 . The optical film of claim 3 , wherein the sinusoidal shape of the structured first major surface in the first cross-section comprises a repeating pattern of a same group of N first sinusoid structures, such that N≤100. 5 . The optical film of claim 1 , wherein the variable pitch is determined from a same predetermined function P(r), r a random number with a probability distribution. 6 . The optical film of claim 1 , wherein the blue, green and red wavelengths are approximately 460, 532 and 633 nm, respectively. 7 . The optical film of claim 1 , wherein a global maximum of each of the blue, green and red transmission bands is less than about 25%. 8 . The optical film of claim 1 , wherein each of the blue, green and red FWHMs is greater than about 0.5 degrees wide. 9 . The optical film of claim 1 , wherein the blue and green FWHMs partially overlap and the green and red FWHMs partially overlap. 10 . The optical film of claim 1 comprising a structured second major surface opposite the structured first major surface. 11 . The optical film of claim 10 , wherein in at least a second cross-section in a second plane substantially orthogonal to the optical film, the structured second major surface has a sinusoidal shape having a variable pitch of greater than about 0.5 microns. 12 . The optical film of claim 11 , wherein the first and second planes are substantially orthogonal to each other. 13 . An integral optical construction comprising the optical film of claim 1 embedded between first and second glass substrates. 14 . A display system comprising the integral optical construction of claim 13 disposed on a display panel. 15 . A display system comprising the integral optical construction of claim 13 disposed between a display panel and a polarizing film. 16 . An optical film for reducing at least one of sparkle and moire in a display system, the optical film comprising at least one structured major surface that in at least a first cross-section in a first plane substantially orthogonal to the optical film, comprises a repeating pattern of a same group of N first structures, such that N≥2, the N first structures arranged in the group at a substantially random spacing S having values in a range from about 0.5 microns to about 500 microns and determined from a same predetermined function S(r), r a random number with a probability distribution, such that for a substantially normally incident light and blue, green, and red wavelengths that are at least 50 nm apart from each other and are disposed within respective blue, green and red wavelength ranges extending respectively from about 420 nm to about 480 nm, about 490 nm to about 560 nm, and about 590 nm to about 670 nm, optical transmissions of the optical film versus transmitted angle for the blue, green and red wavelengths comprise respective blue, green, and red transmission bands disposed at angles greater than about 1 degree and having respective blue, green, and red full width at half maxima, at least two of which at least partially overlap. 17 . The optical film of claim 16 , wherein the probability distribution is a uniform probability distribution. 18 . An optical film for reducing at least one of sparkle and moire in a display system, the optical film comprising at least one structured major surface that in at least a first cross-section in a first plane substantially orthogonal to the optical film, comprises a repeating pattern of a same group of N first structures, such that N≥2, the N first structures arranged in the group at spacings in a range from about 0.5 microns to about 500 microns, such that the spacing between each pair of adjacent structures in the group is K*ΔS microns, ΔS a constant greater than about 0.5 and K an integer randomly chosen between 1 and N−1, K being different for each pair of adjacent structures in the group, such that for a substantially normally incident light and blue, green, and red wavelengths that are at least 50 nm apart from each other and are disposed within respective blue, green and red wavelength ranges extending respectively from about 420 nm to about 480 nm, about 490 nm to about 560 nm, and about 590 nm to about 670 nm, optical transmissions of the optical film versus transmitted angle for the blue, green and red wavelengths comprise respective blue, green, and red transmission bands disposed at angles greater than about 1 degree and having respective blue, green, and red full width at half maxima (FWHMs), wherein at least 20% of the green FWHM overlaps each of the blue and red FWHMs. 19 . The optical film of claim 18 , wherein the blue FWHM overlaps with the red FWHM. 20 . The optical film of claim 18 , wherein N≤100.