The present application relates to methods of making thin-film filters with optical properties varying over at least a length or a width or over time and to a method of manufacturing such flexible thin-film filters.
Multi-spectral imaging and hyper-spectral imaging are relatively new imaging methods that are growing with applications in several areas such as drug discovery and safety testing, biological microscopy, forensic analyses, security, environmental monitoring, textile production, food safety and quality control, and waste recycling and sorting.
Hyperspectral imaging (HSI) is a technique combining imaging and spectroscopy to survey a scene and extract detailed information. Also called imaging spectroscopy, HSI is a powerful, data-processing-intensive method that creates a “data cube” containing information about the properties of a target at hundreds to thousands of narrow wavelength bands within the system's field of view.
Hyperspectral imaging differs from a related technique, multispectral imaging, primarily in the number of wavelength bands and how narrow they are. The multispectral technique typically produces 2-D images of a few to a hundred wavelength bands, each covering tens of nanometers. Multispectral imaging combines two to five spectral imaging bands of relatively large bandwidth into a single optical system.
In contrast, hyperspectral imaging obtains a large 3-D cube of a hundred or even thousands of images, with dimensions (x, y, λ), each representing only a few nanometers in range. Multispectral imaging is faster and easier to process with its smaller data set, while hyperspectral imaging provides much greater complexity of data, higher resolution spectra, and is more versatile, with numerous emerging applications beyond satellite-based imaging.
Most techniques for both hyperspectral and multi-spectral imaging involve either spatially or temporally variable filters.
Some configurations use fixed filters on multiple detector arrays to simultaneously capture multiple image frames within various spectral bands. Some others use filter wheels or linear stages in front of a single detector array to sequentially capture image frames with various filters covering the detector array sequentially. Some use liquid crystal based filters that are tuned using electric stimulus of a liquid crystal cavity refractive index to shift its pass band wavelength.
A trending method involves discretely or continuously varying linear filters with the spectrum gradually shifting from one end of the filter to another end. These filters are usually edge filters (short pass or long pass) or band pass filters with the edge or center wavelength sweeping across a wide spectrum range on a single filter.
Variable filters are made through sophisticated variations of the readily expensive vacuum deposition process, making these filters significantly more expensive than comparable uniform filters. While production of high-performance uniform filters is highly expensive with limited scalability, variable filter production is even more expensive due to the sophisticated motion or lithographical steps added to the deposition process. In addition, traditional variable filters are manufactured on thick glass substrates making them sub-optimal for optical systems that require light weight or compactness.
U.S. Pat. No. 9,597,829 and U.S. Publication 2017/0144915 describe methods of producing thin-film optical filters using thermal drawing of structured preforms. This method allows for production of thin film interference optical filters in the form of all-plastic flexible ultra-thin films and sheets. This method addresses two major drawbacks of the traditional vacuum coated thin film filters by providing significantly higher scalability and also providing ultra-thin filters that can bend and conform to curved surfaces in addition to being considerably more compact.
According to a first aspect of the present invention, a method of making an optical filter film with varying optical properties includes the step of drawing a multilayer polymeric preform into an optical filter and varying at least one environmental condition being a member of the group including of heat, pressure, tension, and a drawing speed, the at least one environmental condition being varied over time or over a distance, or both, and causing a variation in layer thickness within the optical filter. Implementations may include one or more of the following features.
The at least one environmental condition may be heat, where the preform is drawn through a furnace subjecting the preform to a heating power that varies across a width of the furnace or over time or both across the width and over time. To this end, the method may include the step of: positioning heaters on opposite sides of the preform, where the opposite sides of the preform extend along a drawing direction of the preform, the width of the furnace extending across the drawing direction; and drawing the preform through the furnace in the drawing direction.
At least one of the heaters may subject the preform to a heating power varying along the width of the furnace. For example, the heating power may be varied by positioning the at least one heater to enclose an acute angle with the preform.
Additionally or alternatively, the heating power may be varied by heating the at least one heater to different temperatures along the width of the furnace. Additionally or alternatively, the heating power of the furnace may also be varied at least locally over time while the preform is being drawn through the furnace.
Additionally or alternatively, the at least one environmental condition may be a drawing speed, where the preform is drawn through a furnace while the drawing speed of drawing the preform through the furnace varies across a width of the furnace or over time or both across the width and over time, thereby producing a multilayer film with thinner film layers in zones exposed to the higher drawing speed than in zones exposed to the lower drawing speed that have thicker film layers.
For example, the drawing speed may be greater on one side of the width of the furnace than on an opposite side, or the drawing speed may be greater in a central portion of the width of the furnace than on lateral sides.
Additionally or alternatively, the drawing speed may alternate over time between a lower drawing speed and a higher drawing speed.
The method may further include the step of cutting out at least one piece from the multilayer film in a border region forming a transitional area from one of the zones with the thinner film layers to one of the zones with the thicker film layers.
A varying layer thickness may also be achieved by heat and tension, where the preform is drawn through a furnace subjecting the preform to a heating power to form an intermediate filter film, and the intermediate filter film is subsequently exposed to heat in a specified location and to a tension force in at least a longitudinal or lateral direction of the intermediate filter film, so that stretching the intermediate filter film until the layer thickness is permanently reduced in the specified location forms the optical filter having a locally reduced layer thickness.
Further details and benefits will become apparent from the following description of various examples by way of the accompanying drawings. The drawings are provided herewith for purely illustrative purposes and are not intended to limit the scope of the present invention.
In the drawings,
This application describes various variations of thermally drawing thin film optical filters to produce variable filters. The present application also discloses various post-processing methods of modifying a uniform filter made through the thermal drawing process to produce varying filters.
Methods of Producing Variable Filters During a Thermal Draw Process
Now referring to
The furnace 12 has heaters 14 placed across the width of the furnace 12 on opposite sides of the preform 10 to heat the preform 10 as it moves through the furnace 12, into or out of the image plane of
In two examples shown in
In
In an alternative example, the heating zones can be realized by individually controllable heating elements 16 to set predetermined local heating power densities, which can create various heating profiles across the furnace 12. If all heating zones are set to the same temperature (heating power density) reaching the preform, a uniform filter film or sheet will result.
In another example illustrated in
In
Another example of varying the effective temperature or heat power density across the furnace 12 includes non-uniform insulating or heat conductor materials placed in front of uniform heating elements 16 to control the profile of the heat radiation transferred from the heater 14 to the preform. This non-uniformity can be created by varying one of more properties of the material placed between the heater 14 and the preform, such as thickness, porosity, or face dimensions.
Instead of introducing changes to the furnace 12, changes to the preform 10 can be made to create variable filters. One possible configuration is shown in
Notably, the wedged preforms of
Another modification to the geometry can be applied to the layers found within the preform.
Another draw parameter that can be modified to have an effect on the thickness on the film across the film for generating variable filters is the tension and/or draw speed of the draw across the furnace.
A laterally varying drawing speed can be achieved by applying uneven pressure across the width of the preform between opposing rollers that pull the film 26. The uneven pressure may be a higher pressure on one lateral side than on the opposite lateral side by pressing the rollers together at a higher force on one side than on the other side. For attaining a different drawing speed in the center than on the lateral sides of the preform 10, specialty rollers that are not completely straight. Either the core of the roller can be slightly bent or the rubber on the roller can be shaved to create any arbitrary thickness profile that results in a matching pressure (and speed) profile across the width. For achieving a different and changeable distribution of drawing speeds, a different pressure distribution across the width of the rollers and across the furnace may be achieved by forming the rollers of a plurality of roller segments across the width with individually adjustable pressure and/or drawing speed. Generally, rollers or individual roller segments may be made of elastically compressible material for an enhance pressure distribution. The rollers or roller segments may have varying or differing roller diameters so that in locations of greater diameters a greater pressure is exerted to the preform and, due to the greater roller circumference, additionally a locally greater drawing speed is achieved.
In another example, increasing and decreasing the drawing speed and tension over time can be used to induce shifts in the spectrum along the drawn filter film 26 or sheet.
This variation in film thickness provides a further alternative of additional option for creating variable filters. The transition areas between various drawing speeds will form varying filters along the vertical direction. The gradient or step size of changing the drawing speed relative to a feed speed or roller resistance applied to the preform dictate the length along the resulting film 26, over which the spectral shift takes place. Slow speed changes result in slowly varying filters, and vice versa. While the width of the resulting filter film 26 may also vary with varying drawing speed, this effect is of a much smaller proportion than the change in thickness.
Post-Processing Methods of Producing Variable Filters
Creating a filter with varying properties can also be accomplished as part of a post-processing treatment of a uniform filter film 26 or sheet. One example of such a post-processing treatment is illustrated in
In another example, a section of a filter film, which may be uniform or manufactured to have a non-uniform thickness, can be placed in a customized mold or press which slightly heats the filter film. This mold or press can apply varying pressure to various parts of the filter film resulting in a slight change in the filter film thickness and its spectral characteristics. This method can be used with molds with two dimensional variations to create two dimensionally varying filters. For example, a mold press that replicates the curvature of a lens can be used to serve two purposes: (1) slightly bend and stretch the filter film for conforming the filter to the lens surface without inducing stress in the film, and (2) slightly shifting the spectral properties of the filter in a radial pattern to compensate effects of the angle of incidence on filter's spectral shape for light impinging on various parts of the lens at various angles.
In another example, the uniform filter film or sheet can be placed on a surface that may be slightly heated. This surface can have wedged shaped slopes (or uneven surface with various depth profiles) on which the filter film can be placed with the surrounding sections being flat and parallel. A cold or heated roller can then roll over the filter film or sheet to gradually compress the filter film or sheet to various degrees as the rollers goes along the length of the sloped area. This uneven pressure on the filter while it is close to its materials' softening point can induce changes in the filter layer thicknesses and therefore spectral shift following the same depth profile as the uneven (sloped) section of the substrate surface.
Methods of Temporally Varying Filters
All methods and examples disclosed above are related to creating spatially varying filters with varying spectral characteristics across the physical dimensions of the filter, longitudinal or lateral, or both.
Another method of varying a filter's characteristics is through heating. All materials have finite coefficients of thermal expansion (CTE). This causes a change in the thickness of thin film layers, resulting in a shift in the transmission spectrum curve (thermal spectrum drift). In hard-coated traditional filters, this effect has a minimal influence on the spectral characteristics due to the low CTE of hard oxide and other materials used in hard-coated thin-film filters. However, most thermoplastic polymers used for thermally drawing optical filter films and sheets have relatively higher CTE, resulting in a more pronounced spectral drift due to temperature fluctuations. This effect can be brought under control to be used as a method of temporarily varying filter properties and shifting its spectrum. The filter properties change depending on the local temperature so that the optical properties are transient and changeable during use of the filter film.
This can be achieved in a variety of manners. In one configuration, the filter film or sheets can be mounted in a small temperature-controlled holder that can controllably change the temperature in the filter's surrounding. In another configuration, the filter film or sheet can be placed against (or laminated on) a glass substrate that is temperature controlled. This temperature controlling can be achieved by attaching heating and cooling plates (such as thermoelectric generators or modules) to the glass peripheries outside of the filter's clear aperture. It can also be achieved by laminating the filter on a glass substrate that has a transparent conductor coating (such as Indium Tin Oxide, ITO) with high resistance that can cause heating through surface current generation. Examples of ways to mount the filter film in a holder or frame, or on a substrate, are described in WO 2017/180828, which is incorporated herein by reference in its entirety.
These temporary thermally induced filter modifications may be applied to both uniform and variable filters. A filter with temporarily changing optical properties is especially useful in applications where a rapid change of optical properties is not required. For faster changes, a filter having spatially varied properties may be movably installed so that the optical properties are changed by moving the filter perpendicular to a viewing direction.
In summary, various options of manufacturing multilayer filter films with varying optical properties have been presented. Further, methods of modifying optical filters after the drawing process have been described. Two or more of these options and methods may be combined to provide more complex modifications if desired. It is, for example, to be understood that post-processing procedures can be applied to films, whose properties have been modified during the drawing stages of the films. Also, a permanent deformation by heat application may be followed by temporary modifications. Accordingly, all of the provided processes are not mutually exclusive, but complement each other.
While the above description constitutes the preferred embodiments of the present invention, it will be appreciated that the invention is susceptible to modification, variation and change without departing from the proper scope and fair meaning of the accompanying claims.
Filing Document | Filing Date | Country | Kind |
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PCT/US2018/032871 | 5/16/2018 | WO | 00 |
Number | Date | Country | |
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62507432 | May 2017 | US | |
62507432 | May 2017 | US |