Optical filter device

An optical filter transforms defined color light images from television sets, projectors, and the like, into an endless variety of color abstracts. A plurality of light-collector channels conduct light from a color image to a translucent display screen, each channel diffusing and averaging light passing therethrough.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
This invention pertains to optical filters and more particularly to an 
optical filter which transforms defined color light images produced by 
television sets, motion picture projectors, slide projectors, and the 
like, into an endless variety of color abstracts. 
2. Description of the Prior Art 
Display devices, which produce illuminated color displays, are, of course, 
well known. Many of these display devices utilize a self-contained light 
source in combination with one or more rotating color wheels to produce a 
continuously changing color display. See, for example, U.S. Pat. No. 
3,694,645 and U.S. Pat. No. 3,762,082. The color displays produced by such 
devices are, however, limited to the various color combinations produced 
by the rotating or movable color wheels. In addition, such devices are 
relatively costly to produce because of the variety of electrical parts 
including motors, switches, and the like, needed for their construction. 
Moreover, none of these prior art display devices known to applicant 
transforms a defined color image into one or more color abstracts. 
In addition to the above prior art display device, there are display 
devices which produce color displays without the use of any self-contained 
light source or any movable parts. One such device is disclosed by U.S. 
Pat. No. 3,627,926 issued to Jordan. Specifically, Jordan discloses a 
design generator, which generates color designs of black and white moving 
pictures. The design generator comprises a stack of three aligned sheets. 
A pattern sheet has an opaque background with clear or transparent cut out 
portions. Two transparent colored sheets, which may also have cut out 
portions are aligned with the pattern sheet. The colors of the two sheets 
are selected so that both form a third distinct color. In operation the 
design generator is placed in a position to intercept light from a source 
or screen such as a television set or a motion picture projector. So 
intercepted, the intensity of the light passing through the cut out 
portion in the pattern sheet forms a flowing colored design and 
configuration when viewed through the design generator. While this design 
generator produces a colored display without the use of expensive 
electrical parts, the color display is limited to a variation of three 
separate colors resulting from the colored sheets and not from the image 
per se. Thus, even though the colored display is continuously changing, 
the variety of colors that can be displayed are limited. The overall 
effect is therefore not even as artistic as that produced by display 
devices which utilize movable color wheels. Furthermore, neither this 
device nor any of the other prior art display devices discussed above are 
capable of transforming color images, such as an image produced on a 
television screen, into a color abstract. 
These disadvantages of the prior art are overcome by the present invention. 
SUMMARY OF THE INVENTION 
This invention is directed to an optical filter, which transforms defined 
color images produced by a light source, such as a television screen into 
a composite color abstract. 
The principal structural components of the optical filter are a 
light-collector means comprising a preferably solid opaque body perforated 
with a plurality of light collector channels for diffusing and averaging 
colored light rays emitted from a defined color image, and a generally 
planar display screen disposed in a generally parallel confronting 
relation to the light-collector means. In operation, the optical filter is 
preferably disposed so that the light-collector channels are in a position 
to intercept multicolored light rays emitted from at least a portion of a 
defined color image, such as an image displayed on a television screen. 
When so intercepted the light rays are averaged and diffused as they pass 
through the plurality of light-collector channels. The diffused and 
averaged light rays exiting the light-collector channels impinge upon the 
rear surface of the display screen and are thereafter further diffused by 
the display screen so as to produce composite color abstracts which are 
each diffused color composites of the intercepted portion of the color 
image. When the defined color image intercepted by the optical filter is a 
moving image, the plurality of composite color abstracts displayed on the 
display screen will continuously change. 
A different effect is accomplished by adding to the optical filter 
described above, a first partially silvered mirror, which forms the front 
or viewing surface of the device, and a second fully silvered mirror 
having at least one gap for the transmission of light positioned adjacent 
the display screen and behind and generally parallel to the first mirror. 
In operation, colored light transmitted through the gap or gaps in the 
fully silvered mirror results in successive reflections between the two 
mirrors, thereby creating a series of virtual images. The first reflection 
corresponds to the first virtual image, the second reflection corresponds 
to the second virtual image, etc. The multiple virtual images appear to 
extend back into the device so as to impart to the observer an illusion of 
depth. The observer is able to see these images by virtue of light 
transmitted through the partially silvered mirror which forms a front or 
viewing surface. 
Further features of the apparatus according to the invention will become 
apparent from the following detailed description and annexed drawings, 
which disclose certain nonlimiting examples of the embodiment preferred at 
present.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
Referring now to the drawings in detail and initially to FIGS. 1, 2, 9 and 
10 thereof, the preferred optical filter display device of the present 
invention, generally referred to by reference numeral 10, for transforming 
a defined color image into a composite color abstract is shown. As shown 
and preferred in FIGS. 1, 2, 9 and 10, the optical filter 10 preferably 
includes a display screen 12, such as for example, one manufactured of a 
translucent light diffusing material. As presently preferred display 
screen 12 is manufactured as a laminate of a clear plastic material, such 
as for example, an acrylate polymer and a translucent cellulose material, 
such as for example, tracing paper. While such a laminate can be 
manufactured by any suitable means known in the art, it is presently 
preferred to manufacture the laminate by adhesively bonding the two 
material layers together. Other translucent light-diffusing materials can, 
however, be used. Such materials include opal glass, case glass and 
various plastics in either rigid, semi-rigid or flexible form. Examples of 
suitable plastics include acrylic, styrene, cast lucite, polycarbonate, 
polyethylene, polystyrene and polypropylene. In order to further enhance 
the diffusion properties of the display screen 12, front surface 13 of the 
display screen 12 can be textural. Thus, the surface may have a repeating 
textured pattern, such as for example, of a diamond or prismatic shape. 
Alternatively, the front surface 13 of display screen 12 may be uneven 
with hemispherical protrusions extending outwardly from the front surface 
13. 
As shown and as presently preferred, display screen 12 has a rectangular 
peripheral geometric shape. However, it can be of any peripheral geometric 
shape such as circular, elliptical or triangular. Preferably, display 
screen 12 will have the same peripheral geometric shape as light-collector 
means 14 and is disposed in a generally parallel confronting relation to 
the light collector means 14 to which it is fixedly attached. Confronting 
relation is defined herein to include both in a spaced relation, such as 
illustrated on FIG. 12, and in an abutting relation, such as illustrated 
in FIGS. 2, 3C, 10 or 11, by way of example. Preferably, however, and, as 
best shown in FIGS. 2 and 10, rear surface 20 of display screen 12 is in 
abutting relation with front surface 21 of light collector means 14. 
Numerous ways of fixedly attaching display screen 12 to light collector 
means 14 will be obvious to one skilled in the art and any may be used. As 
presently preferred, display screen 12 and light-collector means 14 are 
adhesively bonded together. Alternatively, an injection molding technique 
may be employed to integrally form the display screen 12 and the 
light-collector means 14. In still a further alternative mode of 
construction, the display screen 12 and the light-collector means 14 may 
be held together in a generally parallel confronting relation by means of 
a frame-like housing. 
As shown and preferred in FIG. 9, light-collector means 14 comprises a 
solid rectangular body, which has been perforated so as to provide a 
plurality of light-collector channels 16, which, as will be described in 
greater detail hereinafter, diffuse and average light rays emitted from a 
defined color image so as to produce a plurality of composite color 
abstracts in cooperation with display screen 12. While light-collector 
means 14 may be constructed of any suitable material including cardboard, 
wood and metal, a lightweight material, such as for example, plastic or 
styrofoam is most desirable. As presently preferred an injection molding 
technique is employed to form the light-collector means 14. Such an 
injection molding technique can, if desired, be used to integrally form 
the light-collector means 14. 
As best shown and preferred in FIGS. 1 and 9, the light-collector channels 
16 are circular and arranged in a regular row and column pattern. It has 
been found that light-collector channels having a diameter of from about 
1/2 to about 11/2 inches produce the best results. A diameter of about one 
inch is, however, presently preferred. Like display screen 12, it is 
possible for light-collector means 14 to take any number of peripheral 
shapes, such as for example, circular, elliptical or triangular. However, 
the shape of the light-collector means 14 preferably corresponds to the 
peripheral shape of the display screen 12. 
The length and width (the peripheral dimensions) of light-collector means 
14 can vary greatly, without any effect on its function or operation. 
However, the depth or thickness of the light-collector means 16 is a 
critical dimension, since the light diffusion properties of the 
light-collector means 14 are dependent upon its thickness. It has been 
found that a light-collector means 14 having a thickness of between about 
1/4 inch to about four inches yields the best results. More specifically, 
as the thickness of the light-collector means 14 increases, thereby 
increasing the length of the light-collector channels 16 extending 
therethrough, the amount of light diffusion which occurs as light rays 
emitted from a defined color image pass through the light-collector 
channels 16 will also increase. When constructing the optical filter 
display device of the present invention, the light diffusion properties 
and, thus, the thickness of light-collector means 14 must be considered 
along with the light diffusion properties of display screen 12. It has 
been found that when the display screen 12 is constructed of a material 
which is only mildly light diffusing (such as for example, a laminate of a 
clear plastic and tracing paper) light-collector means 14 must be 
relatively thick (between 1 and 4 inches) so as to be able to diffuse the 
incoming defined color images. Conversely, a highly diffusing display 
screen 12, such as for example, a display screen constructed of 
translucent polycarbonate will permit the use of a relatively thin 
(between 1/4 and 1 inch) light-collector means 14. It is very important, 
however, that the combination of display screen 12 and light-collector 
means 14 be sufficiently light diffusing so as to transform colored light 
emitted from a defined color image into a diffused composite color 
abstract as it passes through optical filter 10, which comprises a 
diffused color composite of the intercepted color image for each of the 
collector channels 16. 
In operation, optical filter 10 is preferably placed in a position to 
intercept defined color images from a source or a screen, which projects 
colored images. Such light sources include, for example, television sets, 
video tape players, video disc playback units, slide projectors and motion 
picture projectors. While the optical filter of the present invention is 
preferably used with a projected light source, it can be used with a 
non-projected light source as will be described in greater detail 
hereinafter. 
As presently preferred and as shown in FIGS. 1 and 2, a television set is 
utilized as the source of the defined color images. As illustrated, 
optical filter 10 is disposed so that light-collector channels 16 are in 
confronting relation with the screen 28 of television set 30 so as to 
intercept defined color images, which are displayed and projected by 
screen 28. The optical filter 10 can either be rested against the 
television set 30 and thereby supported by the set or be attached to the 
television set 30 by any suitable means known in the art. For example, 
optical filter 10 can be secured to the television set 30 by means of an 
adhesive or it can be secured to the television set 30 by means of clamps, 
such as cups, etc. 
When light-collector means 14 is positioned, as shown in FIGS. 1 and 2, 
each light collector channel 16 intercepts at least a portion of the light 
rays emitted by a defined color image, which is displayed and projected by 
television screen 28. The light rays emitted from the defined color image 
enter the input ends 24 of the individual light-collector channels 16. The 
entering colored light rays are diffused and averaged as they pass through 
the individual light-collector channels 16 between input ends 24 and 
output ends 23. The diffused and averaged light rays exit the output ends 
23 of the light-collector channels 16 and impinge upon rear surface 20 of 
display screen 12. The display screen 12 further diffuses the exiting 
diffused light rays so as to produce a plurality of composite color 
abstracts corresponding to the plurality of light-collector channels 16 in 
light collector means 14. 
An example of the transformation which occurs as colored light emitted from 
a defined color image passes through optical filter 10 is illustrated in 
FIG. 16, which shows an exploded view of an individual light-collector 
channel 16 disposed to intercept a portion of a color image displayed on 
the television screen 28. Thus, as shown, light-collector channel 16 is 
disposed so as to intercept red and blue colored light rays emitted from a 
portion of a defined color image represented by the dotted line 45. As the 
blue and red light rays pass through light-collector channel 16 between 
input end 24 and output end 23, they are diffused and averaged. The 
exiting diffused and averaged red and blue light rays are then further 
diffused and averaged by display screen 12 so as to produce a violet 
composite color abstract on front surface 13 of display screen 12, which 
results from the mixing of the red and blue light. It will be apparent 
that when the defined color image contains a variety of different colors 
each of the individual light-collector channels 16 will sample a different 
portion of the defined color image and thus different combinations of 
color. This will result in a plurality of different and unique composite 
color abstracts being displayed on display screen 12. Moreover, when, as 
with a television screen, a moving color image is projected, the composite 
color abstracts on display screen 12 will continuously change. 
The homogeneity of the colors displayed on display screen 12 will vary 
depending on the diameter of light collector channels 16, the diffusing 
property of light-collector means 14 and display screen 12. For example, 
as the diameter of the light-collector channels decrease the color 
homogeneity will increase. 
While the optimum viewing distance will vary depending upon the size of the 
optical filter 10 and, thus, the size of the television set 30, it has 
been found that a viewing distance of about 8 to 10 feet for a 19-inch 
television set and a 16 inch by 20 inch optical filter produces the best 
results. 
When optical filter 10 is utilized with a television set, as shown in FIGS. 
1 and 2, it may be utilized with either synchronized sound, such as for 
example, a television picture and audio, or utilized with non-synchronized 
sound, such as a stereo or radio. Due to the fact that all music is based 
on time, tempo and base, and all visual movement is also based on time, 
tempo and base, synchronization will occur between what would otherwise 
seem to be dissimilar audio and visual sources. For example, a tennis 
match with its more or less repetitive visual movement on the screen, when 
filtered to an unrecognizable abstract pattern, will often match 
(synchronize) with a sound of a repetitive nature such as a metronome, or 
a piece of music in which the beat is regular and constant. The numerous 
points of audible and visible synchronization is both surprising and 
pleasing. 
As a background piece of colored art (silent with the sound of the 
television receiver down or off), the filter provides a constantly moving 
piece of modern art. Even a badly adjusted color set, one in which none of 
the colors is set at an optimum, will produce literally breathtaking 
colors when viewed through the optical filter of the present invention. 
When optical filter 10 is not used with a projected light source or screen, 
it may be hung in a window to catch the natural changing, moving shadows 
during the day, which are cast by leaves from trees, bushes, or the 
changing light and shade produced by passing cars and pedestrians. When 
used in this manner, a sheet of colored gel material may be affixed to the 
input side of the optical filter 10, thereby providing an additional 
source of colored light. Alternatively, small pieces of colored 
transparent cellophane may be inserted into at least some of the 
light-collector channels 16 in light-collector means 14, thereby creating 
random or specific color patterns, which are then transformed by the 
filter into a smoothed out color display on display screen 12. 
FIG. 11 illustrates an alternative embodiment of the optical filter of the 
present invention wherein an input screen 18 is fixedly secured to rear 
surface 16 of light-collector means 14. As previously described in 
connection with display screen 12, input screen 18 can be fixedly secured 
to light-collector means 14 by one of numerous well known methods. The 
input screen 18 is constructed of the same translucent light diffusing 
materials as display screen 12. It will be apparent that since the input 
screen 18 and display screen 12 are manufactured of substantially the same 
translucent light diffusing material, in operation, the optical filter can 
be reversed, thereby making input screen 18 function as the display screen 
and making display screen 12 function as the input screen. 
FIG. 12 illustrates still another embodiment of the present invention, 
wherein display screen 12 is spaced from light-collector means 14. 
Generally, such spacing is of from about 1/16th of an inch to about 1/2 
inch, however, a spacing of from about 1/16th inch to about 1/4 inch is 
preferred. While any means of spacing display screen 12 from 
light-collector means 14 can be employed, as shown in FIG. 12, it is 
presently preferred to utilize a spacer member 22, which can be either 
separately secured to either display screen 12 or light-collector means 14 
or formed as an integral part of either the display screen 12 or the 
light-collector means 14. When the display screen 12 is spaced in this 
manner each color abstract being displayed appears as a light, soft pastel 
rather than as a bright, sharp color. 
FIGS. 4-8 illustrate still other alternative embodiments of the present 
invention. Thus, FIG. 4 illustrates optical filter 10, wherein 
light-collector means 14 is perforated to provide a plurality of large and 
small circular light-collector channels 16 arranged in a regular pattern. 
FIG. 5 illustrates optical filter 10, wherein light-collector means 14 is 
perforated to provide a plurality of large and small circular 
light-collector channels 16 arranged in a regular pattern. FIG. 6 shows 
optical filter 10, wherein light-collector means 14 is perforated to 
provide a plurality of diamond shaped light-collector channels arranged in 
a regular pattern. FIG. 7 illustrates optical filter 10, wherein 
light-collector means 14 is perforated to provide a plurality of 
hexangular shaped light-collector channels 16 arranged in a regular 
pattern. Finally, FIG. 8 illustrates optical filter 10, wherein 
light-collector means 14 is perforated to provide a plurality of circular 
and triangular shaped light-collector channels 16 arranged in an irregular 
pattern. While a number of arrangements for light-collector channels 16 
are illustrated by way of example in FIGS. 4-8, other arrangements are 
within the spirit and scope of the present invention. Thus, 
light-collector channels 16 may be of any desired geometric shape 
including, but not limited to, circular, square, hexangular, rectangular, 
and triangular. Additionally, the light-collector channels 16 may be 
arranged in any desired manner including both regular and irregular 
patterns. 
FIGS. 3A, 3B, and 3C, illustrate still a different embodiment of the 
present invention, wherein optical filter 10 comprises display screen 12, 
light-collector means 14 and input screen 16. The input screen in this 
embodiment is sufficiently light diffusing so that it can also function as 
a display screen for the color light output. As best shown in FIG. 3C, the 
light-collector channels 16 in the light-collector means 14 are tapered. 
This results in the holes on the front side 21 of light-collector means 14 
having a larger diameter than the holes on the rear side 26 of the 
light-collector means 14. Thus, as shown in FIG. 3A, when display screen 
12 faces the viewer each hole actually touches the adjacent holes. 
Conversely, as shown in FIG. 3B, when input screen 18 faces the viewer, 
the holes are much smaller and do not touch the adjacent holes. 
Furthermore, in accordance with this embodiment, the front surface 21 of 
the light-collector means 14 is a light color, such as white, whereas the 
rear surface 26 of said light-collector means is a dark color, such as 
black. Thus, as illustrated in FIG. 3B, when the smaller size openings are 
viewed as the output the abstract colors are displayed against a dark 
opaque background between each opening resulting in an enhancement of the 
color, which makes the color appear bright. When the screen is reversed, 
as shown in FIG. 3A, and the larger size openings are viewed as the 
output, the colors are displayed against a lighter background with the 
colors in each opening touching the opening next to it. This produces a 
higher key of illumination resulting in each color being displayed as a 
light, soft pastel. Thus, according to this variation both sides of the 
optical filter 10 produce entirely different visible displays resulting 
from different renditions of colors from the same input source. 
While not shown, the light-collector channels 16 in light-collector 14 may 
be shaped so as to provide holes having one peripheral geometric shape 
such as, for example, hexagonal on the front side 21 of light-collector 
means 14 and another peripheral geometric shape, such as for example, 
circular on the rear side 26 of light-collector means 14. Such an optical 
filter 10 has both a display screen 12 and an input screen 18 and, thus, 
can also be used to produce two different color displays by simply 
reversing the way optical filter 10 faces the television screen 28. 
While it is presently preferred and the light-collector means 14 is 
depicted in the drawings as having a solid body portion perforated with a 
plurality of light-collector channels 16, the light-collector means 14 can 
alternatively be constructed of a plurality of individual hollow tubular 
members secured together by means of, for example, an adhesive. Any open 
spaces between adjacent tubular members will not substantially affect the 
display result and can, if desired, be filled with either an opaque or 
translucent material. Like the light-collector channels 16 in 
light-collector means 14, the tubular members can be of any desired shape 
and size and be arranged in any desired manner. 
In still another alternative embodiment light-collector means 14 can be 
constructed of individual solid rods of a translucent material, such as 
for example, glass, plastic, etc., which are secured together by means of, 
for example, an adhesive. Again, any spaces between the individual 
adjacent rods will not substantially affect the display result and can, if 
desired, be filled with either a translucent or an opaque material. The 
individual rods can, of course, be of any desired shape and size and can 
be arranged in any desired pattern. 
In still a further alternative, the light-collector means 14 can be 
constructed of a grid-like structure comprising ribs spaced apart and 
extending vertically in parallel lines and ribs spaced apart and extending 
horizontally in parallel lines intersecting the vertical ribs at right 
angles so as to form right angular sections therebetween. Obviously, such 
a grid can be constructed of flexible ribs, which can be shifted from one 
position to another, thus producing a change from one geometric pattern to 
another such as for example, from squares to diamonds. 
As shown in FIG. 13, still another variation according to the invention is 
illustrated. In accordance therewith, optical filter 10 compries input 
screen 18, light-collector means 14, display screen 12, a preferably 
planar and fully silvered rear mirror 32, a preferably planar partially 
silvered front mirror 36 which is in spaced apart parallel relation to 
mirror 32, and a housing 38 for supporting the individual members in their 
defined relation. 
According to the invention, a partially "silvered" mirror is one which will 
reflect a certain percentage of light while transmitting substantially all 
of the remainder, a small amount of absorption and other losses being 
unavoidable. Such a mirror may be constructed in any number of ways well 
known to those skilled in the art, such as by covering one side of a 
transparent substrate such as glass or plastic with a reflective coating 
of, for example, silver or aluminum. Such coatings may be applied in any 
well known manner, such as for example, vapor deposition. Aluminized 
"Mylar" is presently preferred. The relative amount of light reflected and 
transmitted by the mirror is dependent on the reflectivity of the coating 
applied to the substrate. As shown in FIG. 14, the mirror 36 is a planar 
piece of glass with a partially reflective coating 35 applied to its rear 
surface. However, the term "partially silvered" as used above is not 
intended to limit the mirror to one in which a transparent substrate is 
coated with silver, since, as noted above, any reflective coating such as, 
for example, aluminum, will suffice. Rather, the term is generically used 
to describe a mirror having the above described optical property. As 
presently preferred, the mirror 36 should reflect not less than 50% and 
not more than 95% of light incident upon it, with about 90% reflection 
being preferred. 
A "fully silvered" mirror is one which reflects substantially all of the 
light incident upon it, small losses due to absorption and reflection 
being unavoidable. The construction of a fully silvered mirror is similar 
to that of a partially silvered one except that in the case of a fully 
silvered mirror a denser reflective coating 33 is applied and in addition, 
an opaque coating 34 is applied to the rear surface of the mirror. The 
opaque coating may be applied in any number of well known ways, such as 
for example, by painting the rear surface of the mirror. As shown in FIG. 
14, the mirror 32 is a planar piece of glass 38 with a substantially fully 
reflective coating 33 and a black matte finish 34 applied to its rear 
surface. Moreover, opaque coating 34 on mirror 32 is provided with at 
least one gap 40. Since the reflective coating 33 is always partially 
conductive of the light directed through said gap, part will be 
transmitted through said reflective coating and said transparent coating 
and become incident upon mirror 36, causing light passing through said gap 
to be reflected between said mirrors. This will establish multiple virtual 
images of light (42A, 42B, 42C, etc. in FIG. 15), in the shape of the gap 
or gaps which appear to extend back into the device. The effect of these 
multiple virtual images is to impart an illusion of depth to the observer. 
If desired, and as presently preferred, there may be more than one gap and 
the gaps may be of any desired shape or size and may be arranged in any 
desired pattern either regular or irregular. Moreover, some or all of the 
reflective coatings in the gap may be removed to increase the amount of 
light from a source that passes through the gap. 
As previously noted, housing 38 supports display screen 12, light-collector 
means 14, input screen 16, and the mirrors 32 and 36 in a generally 
parallel confronting relation. Numerous ways of constructing a suitable 
housing are obvious to one skilled in the art, and any may be used. As 
shown, housing means 40 include a rectangular shaped member 44 of wood, 
plastic, metal or other suitable material, having a substantially 
rectangular cross section and framing member 46 for holding said member in 
a generally parallel confronting relation. 
In a variation of this embodiment, mirror 32 can take the place of display 
screen 12, which need not be used. If display screen 12 is replaced by 
mirror 32, input screen 16 and light-collector means 14 must be 
sufficiently light diffusing, as described previously. 
To further enhance the aesthetic effect, it is possible for the mirrors of 
said optical filter to take any number of peripheral shapes, such as for 
example, circular or elliptical, their construction not being limited to 
rectangular, periphery depicted in the drawings. Preferably, however, the 
peripheral shapes of display screen 12, input screen 16, light-collector 
means 14, and mirrors 32 and 36 are substantially the same. 
While I have herein shown and described the preferred embodiment of the 
present invention and have suggested modifications therein, other changes 
and modifications may be made therein within the ascope of the appended 
claims without departing from the sphere and scope of this invention.