Variable view window

Abstract

The variable view window enables a user to change the views possible through a window from a given perspective point. One embodiment includes two variable prisms, temperature regulating element, insulating layer, mounting structures, actuator, and software. Objectives of this new art are to maximize refraction, control dipersion, and minimize physical motion.

Description

BACKGROUND FIELD OF INVENTION

This invention relates to windows that are mounted in a building or on a vehicle, specifically to improved design, structure and use of windows.

BACKGROUND-DESCRIPTION OF PRIOR ART

Originally windows were created and manufactured to enable light to enter buildings and to enable those inside to see outside. For centuries the use and construction of windows changed little. Inventors experimented with incorporating different materials resulting in ornamental windows such as stained glass. By late in the twentieth century, advanced windows include many beneficial adaptations. Commonly, multiple panes are used to maximize energy efficiency often with vacuum or with injected gas between the pains. The widow panes incorporate many more substances added during various stages of production. These substances create various beneficial effects such as tinting and to manipulate selected band widths of electromagnetic energy in desirable ways. Most recently windows have incorporated means to adjust between clear and opaque states as desired. This adaptation effectively converges the historic window blind function into the window itself Even with all the advances in window materials and manufacture, the main functions and generally passive role of windows have remained largely unchanged since their original conception and production many centuries ago and subsequent widespread use to this day.

The effect of variable diffraction using fluids was observed in the construction of variable prisms over a century ago. Subsequently, many well documented constructs have employed the variable diffraction effect of fluid prisms and lenses to achieve desirable objectives. Particularly camera lenses, ray stabilizers, laser ray directing devices, and movie projection devices have all widely used the variable diffraction properties of fluid prisms and lenses. Heretofore the concept, design and manufacture of fluid prisms as functioning window panes incorporated into a building or vehicle has not existed. Converging window and fluid prism technologies as herein described provides abundant and valuable benefits heretofore unrecognized and unaddressed in prior art.

SUMMARY

The invention described herein incorporates a variable fluid prism between the panes of a window mounted in a building or on a vehicle. This novel construction enables a user to adjust the view that the window provides from any given single vantage point simply by adjusting the angle contained within the fluid prism. Moreover a second fluid prism is incorporated to reduce dispersion. Also incorporated are temperature regulators, insulators, mounting hardware, and software code to adjust prism angles to minimize diffraction among visible wavelengths.

Objects and Advantages

Accordingly, several objects and advantages of my invention are apparent. The invention increases the functions that a window performs in many circumstances. The invention also improves the aesthetic appeal provided by a window within a building.

Many people can not autonomously adjust their position to see the full hemisphere possible on the outside of a window. By making the window itself adjustable as herein described, the user can select which portion of the external hemisphere she wishes to view from nearly any single vantage point inside a structure. Moreover as provided herein, the view selected can again be altered whenever desired. Similarly, drivers of a vehicle are somewhat restricted regarding their physical mobility. Particularly, the art includes many examples intended to eliminate blind spots in a vehicle. The art described herein enables a driver to manipulate the view provided by the window glass thereby eliminating blind spots without mirrors or reflecting prisms.

The value of each particular window from an aesthetic standpoint is related to the beauty of the view it provides. Heretofore, the view provided by a window in a building was limited to whatever view an architect had the foresight to plan into construction or was later altered externally. Some windows had excellent views and some windows had poor views. The view from any given vantage point within the building was virtually unalterable. As described herein, the present invention enables the view from a single vantage point through a single window to be infinitely altered in nearly a 180 degree hemisphere. Moreover different views can be selected nearly instantly and changed anytime desired. Thus a user can view a sunrise in the east and later a sunset in the west without ever altering their own perspective. Also, a window high up a wall that historically only provided a view of the sky can be adjusted as described herein to provide views of the ground beneath it in any direction. All of these examples include greatly enhanced aesthetic appeal.

Similarly, the practicality of the view that a given window provides has heretofore been unalterable. The addition of mirrors to the external walls of a building or the sides of a vehicle have been used to enable the user to view different directions from a given vantage point. Alternately, cameras and monitors have been used to provide views. This invention uses fluid diffraction within the window to achieve alternate views. If the user wants to view the side walk or drive way outside of the building for example, she can adjust the window diffraction instead of adjusting her vantage point or relying on other technology. If the driver of a vehicle wants to view the blind spot beside her vehicle, she can adjust the side window of her car to provide the view very comfortably through fluid diffraction within the window.

Further objects and advantages will become apparent from a consideration of the drawings and ensuing description.

DRAWING FIGURES

FIG. 1 single fluid prism window

FIG. 2 double fluid prism window

FIG. 3 double fluid columnar window closed

FIG. 4 double fluid columnar window closed, top view

FIG. 5 double fluid columnar window open

FIG. 6 double fluid columnar window open, top view

FIG. 7 single fluid columnar window

REFERENCE NUMERALS IN DRAWINGS

11 interior window pane

13 window mount A

15 cylinder A

17 stretchable seal A

19 middle pane A

21 insulating chamber A

23 exterior pane A

24 refractive fluid A

25 temperature regulator A

27 mounting flange A

29 cylinder B 1

31 mounting assembly B

33 cylinder B 2

35 window bracket B

37 stretchable seal B

39 median pane B

41 exterior pane B

43 refractive fluid B 1

45 temperature regulator B

47 interior pane B

49 refractive fluid B 2

51 window trim B

53 fluid port 2

55 interior pane C

57 median pane C

59 cylinder C

61 temperature regulator C

63 mounting assembly C

65 exterior pane C

67 insulating chamber C

69 middle pane C

71 stretch lining

73 median pane C

75 interior pane C

77 fluid port 2

79 cylinder C 2

81 cylinder C 3

83 fluid column C 1

85 fluid column C 2

87 fluid column C 3

88 fluid column C 4

89 fluid column C 5

91 fluid port 3

93 fluid port 4

95 fluid reservoir 1

97 fluid reservoir 2

99 Fluid pump

101 median pane C

103 cylinder C 4

105 cylinder flange

107 interior pane C

109 vertical stretch wall 1

111 diagonal stretch wall 1

113 vertical stretch wall 2

115 diagonal stretch wall 2

117 pane adhesive

119 stretch lid

121 middle pane C

123 exterior pane C

125 insulating chamber C

DESCRIPTION—FIGS. 1 AND 2 —ALTERNATE EMBODIMENTS

A first embodiment of the variable view window is illustrated in FIGS. 1 and 2 .

FIG. 1 shows the components that form a single fluid prism window. A 11 interior window pane is a rigid material through which some spectrums of electromagnetic radiation pass. It forms one side of the single fluid prism window. Attached to the 11 interior pane are four mounts, 13 window mount A is one such mount. The 13 window mount A forms a rigid connection between the 11 interior window pane and a 15 cylinder A. The 15 cylinder A is similarly fastened to a 19 middle pane A by a mount. The 19 middle pane A is a rigid material through which some spectrums of electromagnetic radiation passes. A 17 stretchable seal A sealably connects the 11 interior window pane to the 19 middle pane A such that a water tight compartment is formed between these panes. The 17 stretchable seal is a stretchable or flexible manufacture. It is often manufactured from materials including rubber or petroleum feed stocks. Filling the compartment between the 11 interior pane and the 19 middle pane A is a 24 refractive fluid A. The 24 refractive fluid A is a fluid with a refractive index (Table V includes a fraction of the fluids that have refractive indices). (Note that the term “fluid” as used throughout this document refers to any substance that is alterable with the shape of its container or tends to take the shape of its container.) A 21 insulating chamber A is formed between the 19 middle pane A and a 23 exterior pane A which are seal ably connected to one another at their edges. The 21 insulating chamber A may be filled with a vacuum or other means of transparent insulation. A 25 temperature regulator A coil is comprised from a barely visible material through which electricity flows. The 25 temperature regulator A communicates with the 24 refractive fluid A. A 27 mounting flange is rigidly connected to the 23 exterior pane A and the 19 middle pane such that the assembly can be securably mounted to a structure.

FIG. 2 shows the components of a double fluid prism window. A 29 cylinder B 1 connects a 47 interior pane to a 39 median pane B. Also connected to the 39 median pane and 29 cylinder B 1 assembly is a 31 mounting assembly B 1 . A 33 cylinder B 2 connects the 39 median pane B to a 41 exterior pane B. The 39 median pane B, 41 exterior pane B, and 47 interior pane B are each formed by rigid materials through which some spectrums of electromagnetic radiation pass. Sealably around the edges of all of these panes and forming two water tight chambers between the three panes is a 37 stretchable seal B. The 37 stretchable seal B can bend and stretch such that panes can move relative to each other. It is often manufactured from materials including rubber or petroleum feed stocks. A 43 refractive fluid B 1 is contained in the chamber between the 41 exterior pane B and the 39 median pane B. The refractive fluid B 1 is a fluid with a refractive index through which some wavelengths of electromagnetic energy passes. A 45 temperature regulator B is housed within the 39 median pane B. The 45 temperature regulator B is barely visible and conducts electricity. A 49 refractive fluid B 2 is contained between the 47 interior pane B and the 39 median pane B. The 49 refractive fluid B 2 is a fluid with a refractive index through which visible light passes. A 51 window trim B goes around the other components. The 51 window trim B is rigidly attached at the edges of the outermost panes, it protects the assembly and adds aesthetic value when installed.

Operation of the Invention in Alternate Embodiments

The components of FIG. 1 combine to form a single fluid prism window. As the 15 cylinder A is caused to expand, it pushes one edge of the 11 interior window pane away from the 19 middle pane. This movement causes the two panes to reside in relatively non-parallel planes. Thus the 24 refractive fluid A forms a prism causing refraction of visible light passing there through. Using multiple cylinders similar to the 15 cylinder A but attached in the other three corners of the panes enables the panes to be moved into many different planes. Cylinders depicted in the drawing are controlled by hydraulic pressure through a remote pump and control mechanism which are well known in the art and therefore not shown. Such movement causes the 24 refractive fluid to form virtually any desired angle less than 90 degrees. Using a fluid with a high refractive index such as methylnapththalene will create a high refraction thus requiring less cylinder extension to achieve high light refraction. Table V lists a fraction of the many possible refractive fluids.) Unfortunately in many refractive fluids, high diffraction across the visible light spectrum will be concomitant with the high light refraction achieved. This causes the user's view to be distorted by color separation. In the FIG. 1 embodiment, the solution to the diffraction and resultant color separation problem is to use a refractive fluid with a low diffraction in the visible spectrum. (Table V discloses the refractive properties of some materials these are a fraction of the refractive fluids that can be utilized). The last column “Ratio” describes the amount of diffraction a given material has as a function of the wavelength range described range. The higher the “Ratio”, the lower the diffraction. Ethyl alcohol (solutions in) for example has a relatively low diffraction with a “Ratio” of −0.024941. Using this fluid will lessen the color separation problem.

The color separation problem posed by diffraction can be easily explored using the “LOSLO” software included herein. This software was developed to operate the fluid prism window and control color separation. Using Snell's Law, it can determine the relative wavelength trajectory differences in any refractory material that cause the color separation. The LOSLO software reveals that an ethyl alcohol (solutions in) prism angle range of −0.216 radians through 0.216 radians can be achieved while maintaining a tolerance of 0.001 radians refracted trajectory difference between the two visible wavelengths listed I Table V. Table I discloses the result when considering three incident angles simultaneously.

TABLE I
Ethyl Alcohol (solutions in) maximum prism angle while maintaining relative trajectory
tolerance of .001 radians across three incident (all angles are in radians).
Incident	Prism	Trajectory of	Trajectory of	Relative
Angle	Angle	1st wavelength	2nd wavelength	Trajectory Angle
0.52	0.216	0.430740593273115	0.431739667349834	−0.000999074076718731
0.32	0.216	0.238811836432108	0.23974608306997	−0.000934246637862124
0.02	0.216	−0.0602629892363292	−0.0593184626870569	−0.000944526549272233

Note that the ray with the initial incident angle of 0.52 has a final trajectory of approximately 0.43. The difference between these angles is 0.09. 0.09 represents the total refraction achieved by the two fluids will cause color separation exceeding the 0.001 relative trajectory level. The user will see color distortion with any relative trajectory difference depending upon their distance from the refracting window. The goal then is to minimize any difference in relative trajectory across the visible spectrum.

FIG. 2 depicts the double fluid prism window. This embodiment presents an alternate solution to the color separation caused by diffraction discussed above. Mounting the assembly with the 31 mounting B and similar mounting hardware on the other corners causes the 39 median pane B to be in a permanently fixed position. Cylinders depicted in the drawing are controlled by hydraulic pressure through a remote pump and control mechanism which are well known in the art and therefore not shown. Expanding and contracting the 29 cylinder B 1 (and similar cylinders located at other corners) will cause the 47 interior pane B to move to different planes relative to the 39 median pane B. This causes the 49 refractive fluid B 2 to form many different prism angles as desired. Similarly, expanding and contracting cylinders such as 33 cylinder B 2 will cause the 41 exterior pane to move to planes non-parallel to the 39 median plane B. Thus forming many possible prism angles with 43 refractive fluid B 1 . The 37 stretchable seal B enables these panes to move relative to each other while still containing their respective refractive fluids. The 45 temperature regulator keeps the fluid at a desired temperature which is desirable since the refractive index of a material generally varies with temperature.

In operation, the double fluid prism window is designed such that one fluid prism does most of the refraction and the other fluid prism neutralizes the diffraction caused by the first prism. The “LOSLO” a software is designed to operate these two fluid prisms such that color distortion caused by diffraction is minimized.

TABLE II
using water as the first refractive fluid and methylnapthalene as the second
refractive fluid, the maximum refraction achievable while maintaining relative
trajectory tolerance of .0001 radians across three incident angles
(all angles are in radians).
Incident	1st Prism	2nd Prism	Trajectory of	Trajectory of	Relative
Angle	Angle	Angle	1st wavelength	2nd wavelength	Trajectory Angle
0.52	0.396	−0.053	0.39837	0.39847	−9.7618E-5
0.32	0.396	−0.053	0.20724	0.20725	−1.7305E-5
0.02	0.396	−0.053	−0.09519	−0.09528	9.2163E-5

Note that the ray with the initial incident angle of 0.52 has a final trajectory of approximately 0.40. The difference between these angles of 0.12 radians represents the total refraction achieved on the two fluids' trajectories. The FIG. 2 embodiment with water and methylnapthalene achieved a 30% (from 0.9 to 0.12) greater refraction than was achieved with the FIG. 1 single fluid prism window with a concomitant 1000% decrease in the diffraction (from 0.001 to 0.0001).

Another example of how the FIG. 2 double fluid prism window can use two fluids together to achieve high refraction and low diffraction is described in Table III.

TABLE III
using octane as the first refractive fluid and pentane as the second refractive fluid, the
maximum refraction achievable while maintaining relative trajectory tolerance of .0005
radians across three incident angles (all angles are in radians).
Incident	1st Prism	2nd Prism	Trajectory of	Trajectory of	Relative
Angle	Angle	Angle	1st wavelength	2nd wavelength	Trajectory Angle
0.52	0.014	−0.431	0.992050137205817	0.991598815447285	0.000451321758532908
0.17	0.014	−0.431	0.386821210548222	0.387130340908125	−0.000309130359902765
0.02	0.014	−0.431	0.211241377302523	0.211665137702471	−0.000423760399948264

Note that the ray with the initial incident angle of 0.52 has a final trajectory of approximately 0.99. The difference between these of 0.47 represents the total refraction achieved on the two fluids' trajectories. Thus the FIG. 2 embodiment with octane and pentane can bend a normal (90 degree) light ray up to 0.47 radians in any direction from the normal to the incident surface.

A second problem posed by both the FIG. 1 and FIG. 2 embodiments is the range of movement that the panes must under go relative to one another in order to achieve high levels of refraction. Assume for example that the 47 interior pane was a four foot square window. In the Table III example, the 2nd prism angle of 0.431 would require that one edge of the window move out from the wall (into the room) about 1.5 feet. Having the window panes undergo movement of this magnitude is often not desirable. It can be aesthetically distracting to look at or it can be bumped into, also very impractical as with automobile windows for example. Larger window sizes with greater movement would often not be practicable using the FIG. 1 and FIG. 2 embodiments.

FIGS. 3 through 7 —Preferred Embodiments

FIG. 3 shows the components that form double fluid columnar window. The window is show in the fully collapsed position.

A 59 cylinder C is in the fully collapsed position as are. Cylinders depicted in the drawing are controlled by hydraulic pressure through a remote pump and control mechanism which are well known in the art and therefore not shown. The 59 cylinder C connects to A 57 median pane C. A 53 fluid port 2 is the means by which fluid enters into one column of the assembly. The 53 fluid port 2 communicates with a chamber housed between two glass panes. A 55 interior pane C forms one side of the window assembly. A 61 temperature regulator C extrudes beyond the 57 median pane C in which it resides. A 63 mounting assembly connects the corner of the 57 median pane C to a structure with protruding bolts.

FIG. 4 shows the top view of the embodiment depicted in FIG. 3 . The components form a double fluid

A 65 exterior pane C forms the outermost surface of the window assembly. Its edges are sealably connected to the 69 middle pane C. A 67 insulating chamber C is formed between these two panes, it may contain a vacuum or other transparent insulating material. A 73 median pane C resides in close proximity to the 69 middle pane C yet between the panes is housed a 71 stretch lining. The lining is a highly elastic material that forms the prismatic surfaces which contain liquids. A 75 interior pane C forms one side of the window assembly. It also resides close to the 73 median pane C. A 77 fluid port 2 communicates fluid to one of the columns residing between the 75 interior pane C and the 73 median pane C of the assembly.

FIG. 5 shows the embodiment depicted in FIGS. 3 and 4 except in the open position. The components form a double fluid columnar window.

A 79 cylinder C 2 connects the 73 median pane C to the 69 middle pane C. It is show in the expanded position pushing the two panes apart. A 81 cylinder C 3 connects the 73 median pane C to the 75 interior pane C. It is shown in the expanded position pushing the two pane apart. A 83 fluid column C 1 has been opened wide by the separation of the 73 median pane C and the 69 middle pane C. For illustration, the top of the 83 fluid column C 1 has been removed. It comprises a three dimensional triangular chamber that is bounded by highly elastic material such as rubber. It is filled with air. Similarly, the 85 fluid column C 2 has been opened and is illustrated with top removed. This column is depicted containing a fluid other air and it one component of the total prismatic effective of one side of this window. Similarly a 87 fluid column C 3 and a 89 fluid column C 5 have been opened by the movement of the 75 interior pane C away from the 73 median pane C. These two columns contain the second refractive fluid. A 91 fluid port 3 and a 93 fluid port 4 are two of the many ports each one communicating with one fluid column. A 95 fluid reservoir 1 contains refractive fluid to e pumped to and from one side of the assembly and a 97 fluid reservoir 2 contains refractive fluid to be pumped to and from the other side of the assembly. A 99 fluid pump is used to convey fluids to and from the assemblies columns and its cylinders.

FIG. 6 shows the top view of the embodiment depicted in FIGS. 3 , 4 , and 5 . The components form a double fluid columnar window.

A 103 cylinder C 4 connects 73 median pane C to a 107 internal pane C. For illustrative purposes, the tops have been removed from these columns. A 109 vertical stretch wall forms the side of a fluid column. A 111 diagonal stretch wall 1 forms half of an “X” shape with the 115 diagonal stretch wall forming the other half of the “X”. Together they with their closest two vertical stretch walls, describe four separate columns including 83 fluid column C 1 and 85 fluid column C 2 . Each of these columns can be filled with fluid or air as desired. A 117 pane adhesive connects the stretch lining material to the 75 interior pane C. A 119 stretch lid covers a series of columns. Normally all columns would be covered by such lids. A 121 middle pane C provides the rigid support for one side of prism columns. It is sealably connected to 123 exterior pane C such that a 125 insulating chamber C is formed.

FIG. 7 illustrates a single fluid columnar window. It has all of the elements described in FIGS. 3 through 6 with the exception that is basically cut in half and uses only one refractive fluid with air.

Operation—Preferred Embodiments FIGS. 3 through 7

FIG. 3 depicts the double liquid columnar window in the closed position. In this position, all prismatic surfaces are parallel to one another and now net refraction is taking place. It is therefore providing the view of a normal window. The cylinders including 59 cylinder C are fully contracted. All of these cylinders are controlled by pressure provided by a pump these elements are well known in the art and are therefore not shown. 63 mounting assembly C is used to mount the assembly onto a structure, similar such hardware is located on the other 3 corners (not shown) of the 57 median pane. This provides a secure mounting to a structure such as a wall while still allowing free movement of required components. FIG. 4 is a top view of the embodiment of FIG. 3 . The 65 exterior pane C contains a ultraviolet filtering material to prevent these rays from effecting the 71 stretch lining. The 65 exterior pane C is sealably fastened to the 69 middle pane C forming a 67 insulating chamber C. The insulating chamber provides a temperature control which is important since the refractory properties of materials vary with temperature. The temperature maintained at higher than room temperature such as 30 degrees C. because it is easier to only have to heat components than it is to cool components.

As depicted in FIG. 5 , extending one set of cylinders pushes including 79 cylinder C 2 pushes the 69 middle pane C away from the 73 median pane C. This causes a set of fluid columns between these two panes to fill with fluid. A 11 of these fluid columns are normally covered with a 119 stretch lid, lids have been removed in the drawing for illustrative purposes. Half of the columns are filled with air such as 83 fluid column C 1 while the other half are filled with a refractive fluid such as 85 fluid column C 2 . Filling one group of these columns on one side of the 73 median pane C will cause the window to refract light in one direction. Filling the other set of the columns on the same side of 73 median pane C will cause the light to refract in the other direction. The columns closest to the exterior and interior panes only receive air as a fluid while columns closest to the median pane only receive the refractive fluid when filled. Fluid is pumped into each column through its own respective port 91 fluid port 3 is one such port. The fluid is pumped from fluid reservoirs 95 and 97 , one for each refractive substance. The 99 fluid pump is used for this function.

Similarly, the cylinders between the 73 median pane C and the 75 interior pane C such as 81 cylinder C 3 are used to move these two panes apart. As the panes move apart, fluid is pumped into the each of the fluid columns. Some of the columns are filled with air and some are filled with a refractive fluid according to the direction of the refraction desired. In practice, the diffraction caused by one side of the assembly is offset by the other side of the assembly. This yields the desired amount of refraction within a reduced amount of diffraction.

FIG. 6 further illustrates the double liquid columnar window in the open position. Note that when expanded, 89 fluid column C 5 will always be filled with a refractive fluid while 83 fluid column C 1 will always be filled with air 87 fluid column C 3 will sometimes be filled with air to refract in one direction but at other times be filled with a refractive fluid to refract in the opposite direction. The prism angles change as each pane is moved relative to the median pane with angles from 0 to 4 degrees easily possible. Meanwhile the prisms on one side of the median pane do most of the refraction while the prisms on the opposite of the median pane neutralize most of the diffraction.

109 , 111 , and 115 all are a stretchable material through which light passes. Transparent latex can be used for this purpose but refractive fluids must be selected carefully such that they do not react with the latex, also the light spectrum passing through the system should be restricted to protect the latex. Fluids such as water and ethyl alcohol will only slowly degrade latex. Table IV illustrates the maximum diffraction achievable with ethyl alcohol (solutions in) as one refractive fluid and water as the second refractive fluid.

TABLE IV
using ethyl alcohol (solutions in) as the first refractive fluid and water as the second
refractive fluid, the maximum refraction achievable while maintaining relative trajectory
tolerance of .001 radians across three incident angles (all angles are in radians).
Incident	1st Prism	2nd Prism	Trajectory of	Trajectory of	Relative
Angle	Angle	Angle	1st wavelength	2nd wavelength	Trajectory Angle
0.52	0.33	−0.77	1.03761533671252	1.0384533945893	−0.000838057876778597
0.32	0.33	−0.77	0.586406225916517	0.587080939555663	−0.000674713639146507
0.02	0.33	−0.77	0.21036029125388	0.211336999892587	−0.000976708638706691

The LOSLO computer software calculates what the second prism angle must be to offset the diffraction caused by the first prism's angle. The software code developed to achieve this is provided herein as Table VI. Thus the angles can be adjusted instantly through the actuating cylinders. Note that the range of normal ray movement possible with these two fluids 1.02 rads.

Advantages

Many advantages of the preferred embodiment are present because the user can see man different views achievable. A range greater than 1.5 radians is possible for a normal ray. Secondly, diffraction can be reduced to a low tolerance level of 0.0001 radians across the visible spectrum. Thirdly, the amount of physical movement to adjust prism angles has been significantly reduced. With miniaturization, movement of less than 1 inch to achieve 1.5 radians of normal ray range is easily possible. Fourthly, this structure is compatible with automobile characteristics. Fifthly, for novelty, the window can be adjusted to alter the color separation caused by diffraction. For example, the user can maximize color separation to provide a uniquely distorted view of outside.

CONCLUSION, RAMIFICATIONS, AND SCOPE

Thus the reader will see that the variable view window of this invention provides a highly functional and reliable means to alter the view provided through a window from any given vantage point. This is useful from aesthetic and functional perspectives.

While my above description describes many specifications, these should not be construed as limitations on the scope of the invention, but rather as an exemplification of one preferred embodiment thereof. Many other variations are possible. For example prism angles can be actuated by any schemes other than pressure. Window panes referred to herein can be manufactured with many materials, many fluids with refractive indices not included herewith can be used, flexible materials must be matched to fluids such that they don't interact with one another.

Accordingly, the scope of the invention should be determined not by the embodiment(s) illustrated, but by the appended claims and their legal equivalents.

TABLE V
Following are the refractive indices of a fraction of the liquids which can function within a
liquid prism, as compiled from referenced sources.
Reference	Temp in K Material	Wavelength	Ref Index
Nikogosyan	288.15 H2O	0.40466	1.34316
Nikogosyan	288.15 H2O	0.43584	1.34062
Nikogosyan	288.15 H2O	0.4471	1.33983
Nikogosyan	288.15 H2O	0.4713	1.33834
Nikogosyan	288.15 H2O	0.48613	1.33753
Nikogosyan	288.15 H2O	0.5016	1.33676
Nikogosyan	288.15 H2O	0.54607	1.33487
Nikogosyan	288.15 H2O	0.577	1.33378
Nikogosyan	288.15 H2O	0.58756	1.33344
Nikogosyan	288.15 H2O	0.5893	1.33339
Nikogosyan	288.15 H2O	0.65628	1.33155
Nikogosyan	288.15 H2O	0.6678	1.33127
Nikogosyan	288.15 H2O	0.70652	1.33041
Nikogosyan	293.15 H2O	0.40466	1.34274
Nikogosyan	293.15 H2O	0.43584	1.34021
Nikogosyan	293.15 H2O	0.4471	1.33942
Nikogosyan	293.15 H2O	0.4713	1.33793
Nikogosyan	293.15 H2O	0.48613	1.33712
Nikogosyan	293.15 H2O	0.5016	1.33635
Nikogosyan	293.15 H2O	0.54607	1.33447
Nikogosyan	293.15 H2O	0.577	1.33338
Nikogosyan	293.15 H2O	0.58756	1.33304
Nikogosyan	293.15 H2O	0.5893	1.33299	wv spread	n spread	ratio	weighted ratio
Nikogosyan	293.15 H2O	0.65628	1.33115
Nikogosyan	293.15 H2O	0.6678	1.33088	−0.30186	0.0127200000	−0.042138739	−31.58328905
					000001	8131586	66036
Nikogosyan	293.15 H2O	0.70652	1.33002
Nikogosyan	298.15 H2O	0.40466	1.34239
Nikogosyan	298.15 H2O	0.43584	1.33971
Nikogosyan	298.15 H2O	0.4471	1.33892
Nikogosvan	298.15 H2O	0.4713	1.33743
Nikogosyan	298.15 H2O	0.48613	1.33663
Nikogosyan	298.15 H2O	0.5016	1.33586
Nikogosyan	298.15 H2O	0.54607	1.33398
Nikogosyan	298.15 H2O	0.577	1.33289
Nikogosyan	298.15 H2O	0.58756	1.33256
Nikogosyan	298.15 H2O	0.5893	1.3325
Nikogosyan	298.15 H2O	0.65628	1.33067
Nikogosyan	298.15 H2O	0.6678	1.3304
Nikogosyan	298.15 H2O	0.70652	1.32954
Nikogosyan	303.15 H2O	0.40466	1.34166
Nikogosyan	303.15 H2O	0.43584	1.33913
Nikogosyan	303.15 H2O	0.4471	1.33835
Nikogosyan	303.15 H2O	0.4713	1.33686
Nikogosyan	303.15 H2O	0.48613	1.33606
Nikogosyan	303.15 H2O	0.5016	1.33529
Nikogosyan	303.15 H2O	0.54607	1.33341
Nikogosyan	303.15 H2O	0.577	1.33233
Nikogosyan	303.15 H2O	0.58756	1.33199
Nikogosyan	303.15 H2O	0.5893	1.33194
Nikogosyan	303.15 H2O	0.6678	1.32984
Nikogosyan	303.15 H2O	0.70652	1.32899
Nikogosyan	288.15 methanol	0.48613	1.3346	wv spread	n spread	ratio	weighted ratio
Nikogosyan	288.15 methanol	0.65628	1.32897	−0.17015	0.0056300000	−0.033088451	−40.16416438
					0000002	3664415	72112
Nikogosyan	293.15 ethenol	0.40466	1.3729	wv spread	n spread	ratio	weighted ratio
Nikogosyan	293.15 ethenol	0.65628	1.3591	−0.25162	0.0138	−0.054844606	−24.78092333
					9469837	33333
Nikogosyan	293.15 ethylene glycol	0.43584	1.44	wv spread	n spread	ratio	weighted ratio
Nikogosyan	293.15 ethylene glycol	0.65628	1.4296	−0.22044	0.0104	−0.047178370	−30.30202153
					5316638	84616
Nikogosyan	293.15 glycerol (glycerine)	0.48613	1.4795	wv spread	n spread	ratio	weighted ratio
Nikogosyan	293.15 glycerol (glycerine)	0.65628	1.4721	−0.17015	0.0074000000	−0.043491037	−33.84835337
					0000007	3200122	8378
Nikogosvan	293.15 hexane	0.48613	1.3795	wv spread	n spread	ratio	weighted ratio
Nikogosyan	293.15 hexane	0.65628	1.373	−0.17015	0.0064999999	−0.038201586	−35.94091538
					9999995	8351452	46157
Nikogosyan	293.15 cyclohexane	0.43584	1.4335	wv spread	n spread	ratio	weighted ratio
Nikogosyan	293.15 cyclohexane	0.65628	1.42405	−0.22044	0.0094499999	−0.042868807	−33.21879174
					9999996	8388675	60319
Nikogosyan	293.15 dichloroethane	0.48613	1.45024	wv spread	n spread	ratio	weighted ratio
Nikogosyan	293.15 dichloroethane	0.65628	1.44189	−0.17015	0.0083500000	−0.049074346	−29.38174652
					0000008	1651489	69458
Nikogosyan	293.15 chloroform	0.43584	1.4546	wv spread	n spread	ratio	weighted ratio
Nikogosyan	293.15 chloroform	0.65628	1.443	−0.22044	0.0115999999	−0.052622028	−27.42197586
					999998	6699321	20694
Nikogosyan	293.15 benzene	0.40466	1.5318	wv spread	n spread	ratio	weighted ratio
Nikogosyan	293.15 benzene	0.65628	1.49663	−0.25162	0.0351700000	−0.139774262	−10.70747911
					000001	777204	85669
Nikogosyan	293.15 nitrobenzene	0.48613	1.57124	wv spread	n spread	ratio	wcighted ratio
Nikogosyan	293.15 nitrobenzene	0.65628	1.54593	−0.17015	0.0253099999	−0.148751101	−10.39272973
					999999	968851	13315
Nikogosyan	293.15 toluene	0.40466	1.52612	wv spread	n spread	ratio	weighted ratio
Nikogosyan	293.15 toluene	0.70652	1.489795	−0.30186	0.0363249999	−0.120337242	−12.38016569
					999999	430265	0296
Nikogosyan	288.15 carbon tetrachloride	0.48613	1.4697	wv spread	n spread	ratio	weighted ratio
Nikogosyan	288.15 carbon tetrachloride	0.65628	1.46005	−0.17015	0.0096499999	−0.056714663	−25.74378316
					9999994	5321771	06219
Nikogosyan	288.15 acetone	0.48613	1.36634	wv spread	n spread	ratio	weighted ratio
Nikogosyan	288.15 acetone	0.65628	1.35959	−0.17015	0.0067500000	−0.039670878	−34.27173903
					0000003	6364974	70369
Nikogosyan	288.15 acetic acid	0.48613	1.37851	wv spread	n spread	ratio	weighted ratio
Nikogosyan	288.15 acetic acid	0.65628	1.37165	−0.17015	0.0068599999	−0.040317367	−34.02131887
					9999987	0290912	75517
Nikogosyan	293.15 dioxane	0.43584	1.4293	wv spread	n spread	ratio	weighted ratio
Nikogosyan	293.15 dioxane	0.65628	1.4202	−0.22044	0.0091000000	−0.041281074	−34.40317450
					0000011	2152065	54941
Nikogosyan	293.15 carbon disulfide	0.40466	1.6934	wv spread	n spread	ratio	weighted ratio
Nikogosyan	293.15 carbon disulfide	0.65628	1.6182	−0.25162	0.0751999999	−0.298863365	−5.414514414
					999999	392258	89362
Marsh	293 silicone oil	0.43584	1.53751	wv spread	n spread	ratio	weighted ratio
Marsh	293 silicone oil	0.6678	1.51279	−0.23196	0.0247199999	−0.106570098	−14.19525762
					999999	292809	13593
Marsh	293 trimethylpentane	0.43583	1.40029	wv spread	n spread	ratio	weighted ratio
Marsh	293 trimethylpentane	0.66781	1.38916	−0.23198	0.0111300000	−0.047978273	−28.95393861
					000001	9891374	6352
Marsh	293 hexadecane	0.43583	1.44419	wv spread	n spread	ratio	weighted ratio
					000001	7590314	31685
Marsh	293 trans-bicyclodecane	0.43583	1.48011	wv spread	n spread	ratio	weighted ratio
Marsh	293 trans-bicyclodecane	0.66781	1.46654	−0.23198	0.0135700000	−0.058496422	−25.07059316
					000001	1053543	13853
Marsh	293 methynaphthalene	0.48613	1 .63958	wv spread	n spread	ratio	weighted rafio
Marsh	293 methynaphthalene	0.66781	1.60828	−0.18168	0.0313000000	0.172280933	−9.335217584
					000001	509468	66451
Marsh	293 methylcyclohexane	0.43583	1 .43269	wv spread	n spread	ratio	weighted ratio
Marsh	293 methylcyclohexane	0.66781	1.42064	−0.23198	0.0120500000	−0.051944133	−27.34938317
					000001	1149242	01242
Gray, D.E.	293 Acetaldehyde	0.486	1.3359				weighted ratio
Gray, D.E.	293 Acetaldehyde	0.589	1.3316	wv spread	nspread	ratio
Gray, D.E.	293 Acetaldehyde	0.656	1.3298	−0.17	0.0060999999	−0.035882352	−37.06
					9999999	9411764
Gray, D.E.	293 acetone	0.486	1.3639				weighted ratio
Gray, D.E.	293 acetone	0.589	1.3593	wv spread	nspread	ratio
Gray, D.E.	293 acetone	0.656	1.3573	−0.17	0.0065999999	−0.038823529	−34.96075757
					9999994	4117643	57579
Gray, D.E.	293 aniline	0.486	1.6041				weighted ratio
Gray, D.E.	293 aniline	0.589	1.5863	wv spread	nspread	ratio
Gray, D.E.	293 aniline	0.656	1.5793	−0.17	0.0248000000	−0.145882352	−10.82584677
					000002	941177	41935
Gray, D.E.	293 methyl alcohol	0.486	1.3331				weighted ratio
Gray, D.E.	293 methyl alcohol	0.589	1.5863	wv spread	nspread	ratio
Gray, D.E.	293 methyl alcohol	0.656	1.3277	−0.17	0.0053999999	−0.031764705	41.79796296
					9999985	8823521	29641
Gray, D.E.	273 ethyl alcohol	0.486	1.3739				weighted ratio
Gray, D.E.	273 ethyl alcohol	0.589	1.3695	wv spread	nspread	ratio
Gray, D.E.	273 ethyl alcohol	0.656	1.3677	−0.17	0.0061999999	−0.036470588	−37.50145161
					9999998	235294	29033
Gray D.E.	293 ethyl alcohol	0.486	1.3666				weighted ratio
Gray D.E.	293 ethyl alcohol	0.589	1.3618	wv spread	nspread	ratio
Gray D.E.	293 ethyl alcohol	0.656	1.3605	−0.17	0.0060999999	−0.035882352	−37.91557377
					9999999	9411764	04918
Gray, D.E.	293 n-propyl alcohol	0.486	1.3901				weighted ratio
Gray, D E.	293 n-propyl alcohol	0.589	1.3854	wv spread	nspread	ratio
Gray, D.E.	293 n-propyl alcohol	0.656	1.3834	−0.17	0.0066999999	−0.039411764	−35.10119402
					9999993	7058819	98511
Gray, D.E.	293 benzene	0.486	1.5132				weighted ratio
Gray, D.E.	293 benzene	0.589	1.5012	wv spread	nspread	ratio
Gray, D.E.	293 benzene	0.656	1.4965	−0.17	0.0167000000	−0.098235294	−15.23383233
					000002	117648	53292
Gray, D.E.	293 bromnaphthalene	0.486	1.6819				weighted ratio
Gray, D.E.	293 bromnaphthalene	0.589	1.6582	wv spread	nspread	ratio
Gray, D.E.	293 bromnaphthalene	0.656	1.6495	−0.17	0.0324	−0.190588235	−8.654783950
					294118	61729
Gray, D.E.	273 carbon disulfide	0.486	1.6688				weighted ratio
Gray, D.E.	273 carbon disulfide	0.589	1.6433	wv spread	nspread	ratio
Gray, D.E.	273 carbon disulfide	0.656	1.6336	−0.17	0.0352000000	−0.207058823	−7.889545454
					000001	529412	54543
Gray, D.E.	293 carbon disulfide	0.486	1.6523				weighted ratio
Gray. D.E.	293 carbon disulfide	0.589	1.6276	wv spread	nspread	ratio
Gray, D.E.	293 carbon disulfide	0.656	1.6182	−0.17	0.0341	−0.200588235	−8.067272727
					294118	27273
Gray, D.E,	293 carbon tetrachloride	0.486	1.4676				weighted ratio
Gray, D.E.	293 carbon tetrachloride	0.589	1.4607	wv spread	nspread	ratio
Gray, D.E.	293 carbon tetrachloride	0.656	1.4579	−0.17	0.0097000000	−0.057058823	−25.55082474
					0000004	529412	22679
Gray, D.E.	293 chinolin	0.589	1.6245	wv spread	nspread	ratio
Gray, D.E.	293 chinolin	0.656	1.6161	−0.17	0.0308999999	−0.181764705	−8.891165048
					999999	882352	54371
Gray, D.E.	293 chloral	0.486	1.4624				weighted ratio
Gray, D.E.	293 chloral	0.589	1.4557	wv spread	nspread	ratio
Gray, D.E.	293 chloral	0.656	1.453	−0.17	0.0093999999	−0.055294117	−26.27765957
					9999985	6470579	44685
Gray, D.E.	293 chloroform	0.486	1.453				weighted ratio
Gray, D.E.	293 chloroform	0.589	1.4467	wv spread	nspread	ratio
Gray, D.E.	293 chloroform	0.656	1.4443	−0.17	0.0087000000	−0.051176470	−28.22195402
					0000015	5882362	2988
Gray, D.E.	287.9 decane	0.486	1.416				weighted ratio
Gray, D.E.	287.9 decane	0.589	1.4108	wv spread	nspread	ratio
Gray, D.E.	287.9 decane	0.656	1.4088	−0.17	0.0071999999	−0.042352941	−33.26333333
					9999987	1764698	33339
Gray, D.E.	293 ether, ethyl	0.486	1.3576				weighted ratio
Gray, D.E.	293 ether, ethyl	0.589	1.3538	wv spread	nspread	ratio
Gray, D.E.	293 ether, ethyl	0.656	1.3515	−0.17	0.0060999999	−0.035882352	−37.66475409
					9999999	9411764	83607
Gray, D.E.	293 ethyl nitrate	0.486	1.392				weighted ratio
Gray, D.E.	293 ethyl nitrate	0.589	1.3853	wv spread	nspread	ratio
Gray, D.E.	293 ethyl nitrate	0.656	1.383	−0.17	0.0089999999	−0.052941176	−26.12333333
					999999	4705876	33336
Gray, D.E.	293 formic acid	0.486	1.3764				weighted ratio
Gray, D.E.	293 formic acid	0.589	1.3714	wv spread	nspread	ratio
Gray, D.E.	293 formic acid	0.656	1.3693	−0.17	0.0071000000	−0.041764705	−32.78605633
					0000011	8823536	80277
Gray, D.E.	293 glycerine	0.486	1.4784				weighted ratio
Gray, D.E.	293 glycerine	0.589	1.473	wv spread	nspread	ratio
Gray, D.E.	293 glycerine	0.656	1.4706	−0.17	0.0078000000	−0.045882352	−32.05153846
					0000003	9411766	15384
Gray, D.E.	293 hexane	0.486	1.3799				weighted ratio
Gray, D.E.	293 hexane	0.589	1.3754	wv spread	nspread	ratio
Gray, D.E.	293 hexane	0.589	1.3734	−0.103	0.0064999999	−0.063106796	−21.76310769
					9999995	1165044	23079
Gray, D.E.	296.3 hexylene	0.486	1.4007				weighted ratio
Gray, D.E.	296.3 hexylene	0.589	1.3945	wv spread	nspread	ratio
Gray, D.E.	296.3 hexylene	0.656	1.392	−0.17	0.0087000000	−0.051176470	−27.19999999
					0000015	5882362	99995
Gray, D.E.	293 methylene iodide	0.486	1.7692				weighted ratio
Gray, D.E.	293 methylene iodide	0.589	1.7417	wv spread	nspread	ratio
Gray, D.E.	293 methylene iodide	0.656	1.732	−0.17	0.0372000000	−0.218823529	−7.915053763
					000001	411765	44084
Gray, D.E.	371.6 naphthalene	0.486	1.6031				weighted ratio
Gray, D.E.	371.6 naphthalene	0.589	1.5823	wv spread	nspread	ratio
Gray, D,E.	371.6 naphthalene	0.656	1.5746	−0.17	0.0285	−0.167647058	−9.392350877
						823529	19299
Gray, D.E.	295.4 nicotine	0.486				weighted ratio
Gray, D.E.	295.4 nicotine	0.589	1.5239	wv spread	nspread	ratio
Gray, D.E.	295.4 nicotine	0.656	1.5198	−0.17	0.0040999999	−0.024117647	−63.01609756
					9999999	0588235	09758
Gray, D.E.	288.1 octane	0.486	1.4046				weighted ratio
Gray, D.E.	288.1 octane	0.589	1.4007	wv spread	nspread	ratio
Gray, D.E.	288.1 octane	0.656	1.3987	−0.17	0.0059000000	−0.034705882	40.30152542
					0000002	3529413	37287
Gray, D.E.	273 almond oil	0.486	1.4847				weighted ratio
Gray, D.E.	273 almond oil	0.589	1.4782	wv spread	nspread	ratio
Gray, D.E.	273 almond oil	0.656	1.4755	−0.17	0.0091999999	−0.054117647	−27.26467391
Gray, D.E.	288.1 anise seed oil	0.486	1.5743				weighted ratio
Gray, D.E.	288.1 anise seed oil	0.589	1.5572	wv spread	nspread	ratio
Gray, D.E.	288.1 anise seed oil	0.656	1.5508	−0.17	0.0235000000	−0.138235294	−11.21855319
					000001	117647	14893
Gray, D.E.	274.4 anise oil	0.486	1.5647				weighted ratio
Gray, D.E.	274.4 anise oil	0.589	1.5475	wv spread	nspread	ratio
Gray, D.E.	274.4 anise oil	0.656	1.541	−0.17	0.0237000000	−0.139411764	−11.05358649
					000001	705883	78903
Gray, D.E.	293 bitter almond oil	0.486	1.5623				weighted ratio
Gray, D.E.	293 bitter almond oil	0.589		wv spread	nspread	ratio
Gray, D.E.	293 bitter almond oil	0.656	1.5391	−0.17	0.0232000000	−0.136470588	−11.27788793
					000001	235295	10344
Gray, D.E.	283 cassia oil	0.486	1.6389				weighted ratio
Gray, D.E.	283 cassia oil	0.589	1.6104	wv spread	nspread	ratio
Gray, D.E.	283 cassia oil	0.656	1.6007	−0.17	0.0382	−0.224705882	−7.123534031
						352941	41361
Gray, D.E.	293.5 casia oil	0.486	1.6314				weighted ratio
Gray, D.E.	293.5 casia oil	0.589	1.6026	wv spread	nspread	ratio
Gray, D.E.	293.5 casia oil	0.656	1.593	−0.17	0.0384	−0.225882352	−7.05234375
						941176
Gray, D.E.	296.5 cinnamon oil	0.486	1.6508				weighted ratio
Gray, D.E.	296.5 cinnamon oil	0.589	1.6188	wv spread	nspread	ratio
Gray, D.E.	296.5 cinnamon oil	0.656	1.6077	−0.17	0.0431000000	−0.253529411	−6.341276102
					000001	764707	08815
Gray, D.E.	273 olive oil	0.486	1.4825				weighted ratio
Gray, D.E.	273 olive oil	0.589	1.4763	wv spread	nspread	ratio
Gray, D.E.	273 olive oil	0.656	1.4738	−0.17	0.0086999999	−0.051176470	−28.79839080
					9999993	5882349	45979
Gray, D.E.	273 rock oil	0.486	1.4644				weighted ratio
Gray, D.E.	273 rock oil	0.589	1.4573	wv spread	nspread	ratio
Gray, D.E.	273 rock oil	0.656	1.4545	−0.17	0.0099000000	−0.058235294	−24.97626262
					0000002	1176472	62626
Gray, D.E.	283.6 turpentine oil	0.486	1.4817				weighted ratio
Gray, D.E.	283.6 turpentine oil	0.589	1.4744	wv spread	nspread	ratio
Gray, D.E.	283.6 turpentine oil	0.656	1.4715	−0.17	0.0102	−0.059999999	−24.525
						9999999
Gray, D.E.	293.7 turpentine oil	0.486	1.4793				weighted ratio
Gray, D.E.	293.7 turpentine oil	0.589	1.4721	wv spread	nspread	ratio
Gray, D.E.	293.7 turpentine oil	0.656	1.4692	−0.17	0.0101	−0.059411764	−24.72910891
					7058823	08911
Gray, D.E.	288.7 pentane	0.486	1.361				weighted ratio
Gray, D.E.	288.7 pentane	0.589	1.3581	wv spread	nspread	ratio
Gray, D.E.	288.7 pentane	0.656	1.357	−0.17	0.004	−0.023529411	−57.6725
						7647059
Gray, D.E.	313.6 phenol	0.486	1.5558				weighted ratio
Gray, D.E.	313.6 phenol	0.589	1.5425	wv spread	nspread	ratio
Gray, D.E.	313.6 phenol	0.656	1.5369	−0.17	0.0189000000	−0.111176470	−13.82396825
					000001	588236	39682
Gray, D.E.	355.7 phenol	0.486	1.5356				weighted ratio
Gray, D.E.	355.7 phenol	0.589		wv spread	nspread	ratio
Gray, D.E.	355.7 phenol	0.656	1.5174	−0.17	0.0182	−0.107058823	−14.17351648
						529412	35165
Gray, D.E.	289.6 styrene	0.486	1.5659				weighted ratio
Gray, D.E.	289.6 styrene	0.589	1.5485	wv spread	nspread	ratio
Gray, D.E.	289.6 styrene	0.656	1.5419	−0.17	0.024	−0.141176470	−10.92179166
					588235	66667
Gray, D.E.	293 thymol	0.486	1.5386				weighted ratio
Gray, D.E.	293 thymol	0.589		wv spread	nspread	ratio
Gray, D.E.	293 toluene	0.486	1.507				weighted ratio
Gray, D.E.	293 toluene	0.589	1.4955	wv spread	nspread	ratio
Gray, D.E.	293 toluene	0.656	1.4911	−0.17	0.0158999999	0.093529411	−15.94257861
					999998	7647047	63524
Gray, D.E.	300.05 Ammonium Chloride	0.486	1.38473				weighted ratio
Gray, D.E.	300.05 Ammonium Chloride	0.589	1.37936	wv spread	nspread	ratio
Gray, D.E.	300.05 Ammonium Chloride	0.656	1.37703	0.17	0.0077000000	0.045294117	−30.40196103
					0000004	6470591	89609
Gray, D.E.	302.75 Ammonium Chloride	0.486	1.35515				weighted ratio
Gray, D.E.	302.75 Ammonium Chloride	0.589	1.3505	wv spread	nspread	ratio
Gray, D.E.	302.75 Ammonium Chloride	0.656	1.3485	0.17	0.0066500000	−0.039117647	−34.47293233
					0000005	0588238	08268
Gray, D.E.	298.65 Calcium chloride	0.486	1.44938
Gray, D.E.	298.65 Calcium chloride	0.589	1.44279	wv spread	nspread	ratio
Gray, D.E.	298.65 Calcium chloride	0.656	1.44	−0.17	0.0093799999	−0.055176470	−26.09808102
					9999994	588235	34543
Gray, D.E.	299.9 Calcium chloride	0.486	1.40206
Gray, D.E.	299.9 Calcium chloride	0.589	1.39652	wv spread	nspread	ratio
Gray, D.E.	299.9 Calcium chloride	0.656	1.39411	−0.17	0.0079500000	−0.046764705	−29.81115723
					0000012	8823537	27039
Gray, D.E.	298.8 Calcium chloride	0.486	1.37876
Gray, D.E.	298.8 Calcium chloride	0.589	1.37369	wv spread	nspread	ratio
Gray, D.E.	298.8 Calcium chloride	0.656	1.37152	−0. 17	0.0072399999	0.042588235	−32.20419889
					9999991	2941171	5028
Gray, D.E.	293.75 Hydrochloric acid	0.486	1.41774
Gray, D.E.	293.75 Hydrochloric acid	0.589	1.41109	wv spread	nspread	ratio
Gray, D.E.	293.75 Hydrochloric acid	0.656	1.40817	−0.17	0.0095700000	0.056294117	−25.01451410
					0000008	6470593	65829
Gray, D.E.	291.75 Nitric acid	0.486	1.40857
Gray, D.E.	291.75 Nitric acid	0.589	1.40181	wv spread	nspread	ratio
Gray, D.E.	291.75 Nitric acid	0.656	1.39893	−0.17	0.0096400000	0.056705882	−24.66992738
						3529417	58919
Gray, D.E.	284 Potash (caustic)	0.486	1.40808
Gray, D.E.	284 Potash (caustic)	0.589	1.40281	wv spread	nspread	ratio
Gray, D.E.	284 Potash (caustic)	0.656	1.40052	−0.17	0.0075600000	−0.044470588	−31.49317460
					0000001	2352942	31746
Gray, D.E.	284 Potassium cloride	0.486	1.34719
Gray, D.E.	284 Potassium cloride	0.589	1.34278	wv spread	nspread	ratio
Gray, D.E.	284 Potassium cloride	0.589	1.34087	−0.103	0.0063200000	−0.061359223	−21.85278639
					000001	3009719	24047
Gray, D.E.	284 Potassium cloride	0.486	1.35645
Gray, D.E.	284 Potassium cloride	0.589	1.35179	wv spread	nspread	ratio
Gray, D.E.	284 Potassium cloride	0.656	1.34982	−0.17	0.0066299999	−0.038999999	−34.61076923
					9999991	9999995	07697
Gray, D.E.	284 Potassium cloride	0.486	1.36512
Gray, D.E.	284 Potassium cloride	0.589	1.36029	wv spread	nspread	ratio
Gray, D.E.	284 Potassium cloride	0.656	1.35831	−0.17	0.0068099999	−0.040058823	−33.90788546
					9999998	5294117	25552
Gray, D.E.	294.6 Soda (caustic)	0.486	1.41936
Gray, D.E.	294.6 Soda (caustic)	0.589	1.41334	wv spread	nspread	ratio
Gray, D.E.	294.6 Soda (caustic)	0.656	1.41071	−0.17	0.0086500000	−0.050882352	−27.72493641
					0000005	9411767	61848
Gray, D.E.	291.07 Sodium chloride	0.486	1.38322
Gray, D.E.	291.07 Sodium chloride	0.589	1.37789	wv spread	nspread	ratio
Gray, D.E.	291.07 Sodium chloride	0.656	1.37562	−0.17	0.0075999999	−0.044705882	−30.77044736
					9999983	3529402	84218
Gray, D.E.	291.07 Sodium chloride	0.486	1.36442
Gray, D.E.	291.07 Sodium chloride	0.656	1.35751	−0.17	0.0069099999	−0.040647058	−33.39749638
					9999997	8235292	20551
Gray, D.E.	291.07 Sodium chloride	0.486	1.34628
Gray, D.E.	291.07 Sodium chloride	0.589	1.34191	wv spread	nspread	ratio
Gray, D.E.	291.07 Sodium chloride	0.656	1.34	−0.17	0.0062799999	−0.036941176	−36.27388535
					9999984	4705873	03194
Gray, D.E.	295.8 Sodium nitrate	0.486	1.39134
Gray, D.E.	295.8 Sodium nitrate	0.589	1.38535	wv spread	nspread	ratio
Gray, D.E.	295.8 Sodium nitrate	0.656	1.38283	−0.17	0.0085100000	−0.050058823	−27.62410105
					0000002	5294119	75793
Gray, D.E.	293.3 Sulfuric acid	0.486	1.44168
Gray, D.E.	293.3 Sulfuric acid	0.589	1.43669	wv spread	nspread	ratio
Gray, D.E.	293.3 Sulfuric acid	0.656	1.43444	−0.17	0.0072400000	−0.042588235	−33.68160220
					0000014	2941184	99441
Gray, D.E.	293.3 Sulfuric acid	0.486	1.42967
Gray, D.E.	293.3 Sulfuric acid	0.589	1.42466	wv spread	nspread	ratio
Gray, D.E.	293.3 Sulfuric acid	0.656	1.42227	−0.17	0.0074000000	−0.043529411	−32.67377027
					0000007	7647063	027
Gray, D.E.	293.3 Sulfuric acid	0.486	1.37468
Gray, D.E.	293.3 Sulfuric acid	0.589	1.37009	wv spread	nspread	ratio
Gray, D.E.	293.3 Sulfuric acid	0.656	1.36793	−0.17	0.0067499999	−0.039705882	−34.45157037
					9999981	3529401	03713
Gray, D.E.	293.3 Sulfuric acid	0.486	1.34285
Gray, D.E.	293.3 Sulfuric acid	0.589	1.33862	wv spread	nspread	ratio
Gray, D.E.	293.3 Sulfuric acid	0.656	1.33663	−0.17	0.0062200000	−0.036588235	−36.53168810
					0000011	2941183	28932
Gray, D E.	299.9 Zinc chloride	0.486	1.40797
Gray, D.E.	299.9 Zinc chloride	0.589	1.40222	wv spread	nspread	ratio
Gray, D.E.	299.9 Zinc chloride	0.656	1.39977	−0.17	0.0081999999	−0.048235294	−29.01962195
					9999999	117647	12196
Gray, D.E.	296.4 Zinc chloride	0.486	1.38026
Gray, D.E.	296.4 Zinc chloride	0.589	1.37515	wv spread	nspread	ratio
Gray, D.E.	296.4 Zinc chloride	0.656	1.37292	−0.17	0.0073400000	−0.043176470	−31.79787465
					0000012	588236	94
Gray, D.E.	298.5 Ethyl alcohol	0.486	1.36395
Gray, D.E.	298.5 Ethyl alcohol	0.589	1.35971	wv spread	nspread	ratio
Gray, D.E.	298.5 Ethyl alcohol	0.656	1.35971	−0.17	0.0042400000	−0.024941176	−54.51667452
					0000002	4705884	83016
Gray, D.E.	300.6 Ethyl alcohol	0.486	1.35986
Gray, D.E.	300.6 Ethyl alcohol	0.589	1.35556	wv spread	nspread	ratio
Gray, D.E.	300.6 Ethyl alcohol	0.656	1.35372	−0.17	0.0061400000	−0.036117647	−37.48084690
					0000003	0588237	55373
Gray, D.E.	289 Fuchsin (nearly	0.486	1.3918
	saturated
Gray, D.E.	289 Fuchsin (nearly	0.589	1.398	wv spread	nspread	ratio
	saturated
Gray, D.E.	289 Fuchsin(nearly	0.656	1.361	−0.17	0.0307999999	−0.181176470	−7.512012987
	saturated				999999	588235	013
Gray, D.E.	289 Cyanin (saturated)	0.486	1.3831
Gray, D.E.	289 Cyanin (saturated)	0.589		wv spread	nspread	ratio
Gray, D.E.	289 Cyanin (saturated)	0.656	1.3705	−0.17	0.0125999999	−0.074117647	−18.49087301
					999999	0588232	58731

TABLE VI
LOSLO software code written in C++ controls the two prism angles to
minimize diffraction.
//-------------------------------------------------------------
#include <vcl.h>
#include <math.h>
#pragma hdrstop
#include “Thread.h”
#include “Convert.h”
#inciude “OutputT.h”
#include “Imput.h”
#pragma package(smart_init)
double convert(AnsiString);
int p;
//------------------------------------------------------------
void_fastcall TMain::Progress()
{
MainForm−>ProgressBar−>Position = p;
}
//------------------------------------------------------------
__fastcall TMain::TMain(bool CreateSuspended): TThread(CreateSuspended)
{
Priority = tpNormal;
FreeOnTerminate = true;
}
//------------------------------------------------------------
void _fastcall TMain::Execute()
{
double Incl = convert(InputForm—>TIncl−>Text);
if(InputForm−>Inc1N−>Checked == true) Inc 1 = Inc1 * −1;
double Inc2 = convert(InputForm−>TInc2−>Text);
if(InputForm−>Inc2N−>Checked == true) Inc2 = Inc2 * −1;
double Inc3 = convert(InputForm−>TInc3−>Text);
if(InputForm−>Inc3N−>Checked = true) Inc3 = Inc3 * −1;
double Mat2L = convert(InputForm−>TMat2L−>Text);
double Mat2H = convert(InputForm−>TMat2R−>Text);
double Off2B = convert(InputForm−>TOff2B−>Text);
double Off2E = convert(InputForm−>TOff2E−>Text);
double Off2I = convert(InputForm−>TOff2I−>Text);
double Off3B = convert(InputForm−>TOff3B−>Text);
if(InputForm−>Off3BN−>Checked = true) Off3B = Off3B * −1;
double Off3E = convert(InputForm−>TOff3E−>Text);
double Off3I = convert(InputForm−>TOff3I−>Text);
double Mat3B = convert(InputForm−>TMat3B−>Text);
double Mat3E = convert(InputForm−>TMat3E−>Text);
double Mat3I = convert(InputForm−>TMat3I−>Text);
double Tol1 = convert(InputForm−>TTol1−>Text);
double Tol2 = convert(InputForm−>TTol2−>Text);
double Tol3 = convert(InputForm−>TTol3−>Text);
//--------------------------------------------------------------------
double Mat3L = Mat3B;
double Mat3H = Mat3B;
double Off2 = Off2B;
double Off3 = Off3B;
double Ref1L = 0;
double Ref1H = 0;
double Ref2L = 0;
double Ref2H = 0;
double Ref3L = 0;
double Ref3H = 0;
double x = 0;
double loop;
if(Mat3I != 0){
if(Mat3B != Mat3E) loop = 1/((Mat3E−Mat3B)/Mat3I)*100;}
double count = 0;
if(Mat3E == Mat3B ){
p = 100;
Syncnronize(Progress);}
double Range;
Range = 2;
if(Mat3T == 0)
{
Mat3I = 1;
Mat3H = Mat3B;
Mat3L = Mat3E;
Range = Mat3L − Mat3H;
p = 100;
Synchronize(Progress);
};
while (Mat3H <= Mat3E)
{
while (Mat3L <= Mat3H + Range)
{
while (Off2 <= Off2E)
{
while (Off3 <= Off3E)
{
if (MainForm−>Start−>Enabled)
{
Ref3L = 0;
Ref3H = 0;
Ref1H = asin(sin(Inc1)/Mat2H);
Ref2L = asin(Mat2L * sin(Ref1L−Off2)/Mat3L);
Ref2H = asin(Mat2H * sin(Ref1H−Off2)/Mat3H);
x = Mat3L * sin(Ref2L−Off3);
if(fabs(x) < 1)Ref3L = asin(x)+Offf2+Off3;
x = Mat3H * sin(Ref2H−Off3);
if (fabs(x) < 1) Ref3H = asin(x)+Off2+Off3;
double Rel1 = Ref3L − Ref3H;
if(fabs(Rel1) < Toll)
{
if(Ref3L != 0 && Ref3H ′= 0)
{
if (MainForm−>List−>Items−>Count > 20000)
{
MainForm−>Start−>Caption = “Next”;
Suspend();
};
AnsiString Inc1a = Inc1;
AnsiString Off2a = Off2;
AnsiString Off3a = Off3;
AnsiString Mat3La = AnsiString(Mat3L);
AnsiString Mat3Ha = AnsiString(Mat3H);
AnsiString Ref3L1 = AnsiString(Ref3L);
AnsiString Ref3H1 = AnsiString(Ref3H);
AnsiString Relaa = AnsiString(Rel1);
if (Inc2 == Inc1) MainForm−>List−>Items−>Add(““+ Inc1a +”“+ Off2a +”“+
Off3a +” “+ Mat3La +” “+ Mat3Ha +” “+ Ref3L1 +” “+ Ref3H1 +” “+Rel1);
else
{
Ref3L=0;
Ref3H=0;
Ref1L = asin(sin(Inc2)/Mat2L);
Ref1H = asin(sin(Inc2)/Mat2H);
Ref2L = asin(Mat2L * sin(Ref1L-Off2)/Mat3L);
Ref2H = asin(Mat2H * sin(Ref1H-Off2)/Mat3H);
x = Mat3L * sin(Ref2L−Off3);
if (fabs(x) < 1) Ref3L = asin(x)+Off2+Off3;
x = Mat3H * sin(Ref2H−Off3);
if (fabs(x) < 1) Ref3H = asin(x)+Off2+Off3;
double Rel2 = Ref3L − Ref3H;
if (fabs(Rel2) < Tol2)
{
if(Ref3L != 0 && Ref3H != 0)
{
AnsiString Inc2a = Inc2;
AnsiString Ref3L2 = AnsiString(Ref3L);
AnsiString Ref3H2 = AnsiString(Ref3H);
AnsiString Rel2a = AnsiString(Rel2);
if (Inc3 == Inc2)
MainForm−>List−>Items−>Add(““+ Inc1a +” “+ Off2a +” “+ Off3a
+” “+ Mat3La +” “+ Mat3Ha +” “+ Ref3L1 +” “+ Ref3H1 +” “+ Rel1);
MainForm−>List−>Items−>Add (““+ Inc2a +” “+ Off2a +” “+
Off3a +” “+ Mat3La +” “+ Mat3Ha +” “+ Ref3L2 +” “+ Ref3H2 +” “+ Rel2);
}
else
{
Ref3L =0;
Ref3H=0;
Ref1L = asin(sin(Inc3)/Mat2L);
Ref1H = asin(sin(Inc3 )/Mat2H);
Ref2L = asin(Mat2L * sin(Ref1L−Off2)/Mat3L);
Ref2H = asin(Mat2H * sin(Ref1H−Off2)/Mat3H);
x = Mat3L * sin(Ref2L−Off3);
if(fabs(x) < 1) Ref3L = asin(x)+Off2+Off3;
x = Mat3H * sin(Ref2H−Off3);
if (fabs(x) < 1) Ref3H = asin(x)+Off2+Off3;
double Rel3 = (Ref3L − Ref3H);
if (fabs(Rel3) < Tol3)
{
if(Ref3L != 0 && Ref3H != 0)
{
AnsiString Inc3a = Inc3;
Ansistring Ref3L3 = AnsiString(Ref3L);
AnsiString Ref3H3 = AnsiString(Ref3H);
AnsiString Rel3a = AnsiString(Rel3);
MainForm−>List−>Items−>Add(““+ Inc1a +” “+ Off2a +” “+
Off3a +” “+ Mat3La +” “+ Mat3Ha +” “+ Ref3L1 +” “+ Ref3H1 +” “+ Rel1);
MainForm−>List−>Items−>Add (““+ Inc2a +” “+ Off2a +” “+
Off3a +” “+ Mat3La +” “+ Mat3Ha +” “+ Ref3L2 +” “+ Ref3H2 +” “+ Rel2);
MainForm−>List−>Items−>Add (““+ Inc3a +” “+ Off2a +” “+
Off3a +” “+ Mat3La +” “+ Mat3Ha +” “+ Ref3L3 +” “+ Ref3H3 +” “+ Rel3);
};
};
};
};
};
};
};
};
Off3 = Off3 + Off3I;
{
else{
Mat3L = 2;
Mat3R = 2;
Off3 = 2;
Off2B = 2;
Off2B = 2;
}
off2 = Off2 + Off2I;
Off3 = Off3B;
}
Mat3L = Mat3L + Mat3I;
Off2 = Off2B;
}
Mat3H = Mat3H + Mat3I;
Mat3L = Mat3H;
count = count + loop;
p = int(count);
Synchronize(Progress);
}
p = 0;
Synchronize(Progress);
if(MainForm−>Start−>Caption == “Stop”) MainForm−>Start−>Caption = “Start”;
MainForm−>Start−>Enabled=true;
}
//-------------------------------------------------------

Claims

1. An optical system adapted for selecting the resultant trajectory of an incident beam of electromagnetic energy comprising:a) a first variable prism; b) a second variable prism; c) a computer in communication with at least one said variable prism so as to send a signal to vary said prism's affect on said resultant trajectory; and d) wherein spectral dispersion of said beam caused by the first prism is reduced by the second prism.

2. The optical system described in 1, wherein a means is provided for altering the temperature of at least one said variable prism.

3. The optical system described in 1, wherein a means is provided for mounting said system within the wall of a building.

4. The optical system described in 1, wherein a means is provided for mounting said system on a vehicle.

5. The optical system described in 1, further including an array of prisms similar to said first variable prism wherein constituent prisms of said array are operated in unison to function as one large variable prism.

6. The optical system described in 1, wherein the shape of at least one said variable prism is alterable due to the elastic properties of a membrane through which said incident beam must pass before achieving said resultant trajectory.

7. An optical system adapted for selecting the resultant direction of an incident beam of electromagnetic energy comprising: a) a first variable prism; b) a second variable prism; c) a means to adjust the temperature of at least one said prism; and d) wherein spectral dispersion of said beam caused by the first prism is reduced by the second prism.

8. The optical system described in 7, wherein a computer is in communication with at least one said variable prism so as to send a signal to vary said prism's affect on said resultant trajectory.

9. The optical system described in 7, wherein a means is provided for mounting said system within the wall of a building.

10. The optical system described in 7, wherein a means is provided for mounting said system on a vehicle.

11. The optical system described in 7, further including an array of prisms similar to said first variable prism wherein constituent prisms of said array are operated in unison to function as one large variable prism.

12. The optical system described in 7, wherein the shape of at least one said variable prism is alterable due to the elastic properties of a membrane through which said incident beam must pass before achieving said resultant trajectory.

13. An optical system adapted for selecting the resultant direction of an incident beam of electromagnetic energy comprising:a) a first variable prism array consisting of at least two similar prisms operated in unison; b) a second variable prism array consisting of at least two similar prisms operated in unison; and d) wherein said beam passing through the first prism array experiences spectral dispersion which is reduced by the second prism array.

14. The optical system described in 13, wherein a computer is in communication with at least one said prism so as to send a signal to vary said prism's affect on said resultant beam.

15. The optical system described in 13, wherein a means is provided for mounting said system within the wall of a building.

16. The optical system described in 13, wherein a means is provided for mounting said system on a vehicle.

17. The optical system described in 13, wherein a means is provided for altering the temperature of at least one said prism.

18. The optical system described in 13, wherein the shape of at least one prism within one said variable prism array is alterable due to the elastic properties of a membrane through which said incident beam must pass before achieving said resultant direction.

19. An optical system adapted for selecting the resultant direction of an incident beam of electromagnetic energy comprising:a) a first variable prism; b) a second variable prism; c) wherein the shape of at least one said prism is alterable due to the elastic properties of a membrane through which said incident beam must pass before achieving said resultant direction; and d) wherein spectral dispersion caused by the first prism is reduced by the second prism.

20. The optical system described in 19, wherein a computer is in communication with at least one said variable prism so as to send a signal to vary said prism's affect on said resultant trajectory.

21. The optical system described in 19, wherein a means is provided for mounting said system within the wall of a building.

22. The optical system described in 19, wherein a means is provided for mounting said system on a vehicle.

23. The optical system described in 19, further including an array of prisms similar to said first variable prism wherein constituent prisms of said array are operated in unison to function as one large variable prism.

24. The optical system described in 19, wherein a means is provided for altering the temperature of at least one said variable prism.