COMPACT IMAGING SYSTEM USING A CO-LINEAR, HIGH-INTENSITY LED ILLUMINATION UNIT TO MINIMIZE WINDOW REFLECTIONS FOR BACKGROUND-ORIENTED SCHLIEREN, SHADOWGRAPH, PHOTOGRAMMETRY AND MACHINE VISION MEASUREMENTS
One aspect of the present disclosure is an imaging system including an optical sensor defining an optical axis. The system further includes a light source. The system may include an optical beam splitter, and may also include an optional diffusing lens that may be configured to diffuse and/or collimate light from the light source and direct light exiting the diffusing lens to the optical beam splitter. The optical beam splitter is configured to direct light from the light source along the optical axis of the optical sensor.
This patent application claims the benefit under 35 U.S.C. § 119(e) to U.S. Provisional Patent Application No. 63/024,958, filed May 14, 2020, entitled “COMPACT IMAGING SYSTEM USING A CO-LINEAR, HIGH-INTENSITY LED ILLUMINATION UNIT TO MINIMIZE WINDOW REFLECTIONS FOR BACKGROUND-ORIENTED SCHLIEREN AND MACHINE VISION MEASUREMENTS,” which is incorporated by reference in its entirety for any and all non-limiting purposes.
STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENTJoint Government, Large Business, Small business or Nonprofit Organization Invention: The invention described herein was made in the performance of work under NASA contracts and by an employee/employees of the United States Government and is subject to the provisions of the National Aeronautics and Space Act, Public Law 111-314, § 3 (124 Stat. 3330, 51 U.S.C. Chapter 201) and 35 U.S.C. § 202, and may be manufactured and used by or for the Government for governmental purposes without the payment of any royalties thereon or therefore. In accordance with 35 U.S.C. § 202, the contractor elected not to retain title.
BACKGROUNDVarious imaging techniques have been developed to produce images showing variations in density of a gas or other material having density gradients. These imaging techniques may be used in wind tunnels or other creations involving flow of air and/or other materials. Known imaging techniques include schlieren and shadowgraph imaging techniques. In known schlieren techniques, a direct line-of-sight through the test section, a set of high quality lenses or mirrors, and a point illumination source are all typically required for a measurement to be performed. Background-oriented schlieren techniques (BOS) have also been developed. BOS techniques may be sensitive to gradients in density. This sensitivity comes from measurement of small distortions in an image background pattern captured with and without the density gradients present in the test section (where the test section generally refers to anything between the camera and the background pattern). The relatively straight-forward equations that govern the apparent distortion absorbed in the image-background pattern make the BOS technique capable of providing quantitative information pertaining to the visualized density field. BOS differs from conventional schlieren techniques, where the imaged intensity variations are related to the density gradients in the test section. The use of a background pattern and camera permit the BOS technique to be scaled to an arbitrary field-of-view. Although this scalability may be achieved in some cases using direct shadowgraph, the shadowgraph method is primarily a qualitative tool. Multi-camera schlieren tomographic systems for wind tunnel measurements have also been developed. However, known imaging systems and techniques may suffer from various drawbacks.
BRIEF SUMMARYOne aspect of the present disclosure is an imaging system that may be utilized for BOS imaging applications, shadowgraph, photogrammetry, machine vision applications, and other applications. The system includes an optical sensor, such as a digital camera defining an optical axis. The system further includes a light source. The light source may comprise an LED or other suitable device. The system further includes an optical beam splitter, and may include an optional diffusing lens that is configured to diffuse and concentrate light from the LED light source and direct light exiting the diffusing lens to the optical beam splitter. The optical beam splitter is configured to direct light from the light source along the optical axis of the digital camera.
Light coupled onto the optical axis by the optical beam splitter may have a minimum cross-sectional size that is about equal to a size of the diffusing lens. The digital camera may include an imaging lens defining a lens diameter, and the light coupled onto the optical axis may have a minimum diameter that is at least as large as the lens diameter. This aspect of the design minimizes the presence of shadows projected onto the image plane, which may arise from refractive index gradients in the measurement region. The optical beam splitter may comprise a 50/50 beam-splitting plate, cube, or other suitable beam-splitting device. The light source may be configured to produce a short-duration, high-intensity illumination pulse. The duration may be less than about 10 microseconds, less than about 5 microseconds, or less than about 1 microsecond in certain embodiments, however, those of ordinary skill in the art will appreciate that other durations are within the scope of this disclosure. The duration and intensity of light may be set (adjusted) as required or beneficial for a particular application, and in certain embodiments the intensity may be substantially continuous. In general, shorter light pulses may be utilized, if required or beneficial, for higher flow velocities in high speed wind tunnels or other applications.
The digital camera, light source, optical beam splitter, and diffusing lens may be rigidly interconnected to form an imaging unit. A plurality of imaging units, each including a digital camera, a light source (e.g. LED), and an optical beam splitter may be utilized if required or beneficial for a particular application. The optical axes of the imaging units may be radially spaced about a test region. A system may include at least one background pattern aligned with each optical axis, whereby at least some light from the light source of each imaging unit is reflected back to the digital camera of each imaging unit, whereby the digital cameras capture images of the background patterns. The images include variations due to density gradients in a fluid in the test region, whereby the images can be processed to provide background-oriented schlieren (BOS) images. Each camera may be configured to provide a 2-dimensional BOS image, and synchronous images may be inputted to a tomographic algorithm to back out a tomographic reconstruction.
The system may include a controller, such as an electrical circuit programmable controller, or other suitable device. The controller may be configured to simultaneously actuate the digital cameras of each imaging unit, and to simultaneously actuate the light sources of each imaging unit. The controller may, optionally, be configured to generate a camera actuation signal to the digital cameras followed by an actuation signal to the light sources, whereby the electrical circuitry compensates for a time delay of the digital cameras relative to the light sources, and causes the light sources to generate a pulse of light in a manner that is synchronized with actuation of the cameras.
Each imaging unit may include a support structure, such as a housing, and the digital camera, light source, and optical beam splitter may be supported by the housing. Each imaging unit may be supported by an adjustable bracket having a first part and a base part. In accordance with one embodiment, the first part of the adjustable bracket may be rigidly connected to the housing. The first part of the adjustable bracket may also be adjustably connected to the base part, such that the first part can be rotated and translated relative to the base about three axes to a selected position. The imaging units may be utilized in a wind tunnel having sidewalls disposed about the test region. The sidewalls of the wind tunnel may include light-transmitting material forming windows, and the optical axis of each imaging unit may be aligned with an opening. The imaging units may be disposed outside of the wind tunnel with the optical axis of each camera passing through a window of the wind tunnel. The digital camera may optionally comprise a CMOS or CCD device, the light source may optionally comprise a blue, green, or red LED, and the optical beam splitter may comprise a 50/50 beam-splitting plate or cube. Alternatively, the light source may comprise a U.V. light source (e.g., LED). It will be understood that virtually any suitable light source may be utilized as required or beneficial for a particular application.
Another aspect of the present disclosure is an imaging system including a digital camera defining an optical axis and a light source that is configured to generate light traveling transverse relative to the optical axis of the digital camera. The imaging system further includes an optical beam splitter that is configured to couple light from the light source and direct a coaxial beam of light along the optical axis of the digital camera.
The imaging system may include an aperture positioned between the light source and the optical beam splitter to block a portion of the light from the light source such that only light traveling through the aperture reaches the optical beam splitter. The coaxial beam of light may be suitable for producing shadowgraphs.
Optionally, a diffusing lens may be positioned between the light source and the optical beam splitter, whereby light from the light source passes through the aperture and through the diffusing lens.
The imaging system may optionally include a substantially rigid support structure which may be in the form of a module, bracket, or housing. The digital camera, the light source, and the optical beam splitter may be secured to the substantially rigid housing to form an imaging unit.
Another aspect of the present disclosure is a method of generating images. The method includes providing a plurality of imaging units, each imaging unit including a digital camera defining an optical axis, a light source, and an optical beam splitter. The beam splitter is used to cause light from each light source to be coupled onto the optical axis of each digital camera in the form of a coaxial beam. The imaging units are positioned about a test space, and the coaxial beams of imaging units pass through a substance in the test space. The coaxial beams are reflected back to the digital cameras from background patterns. Data from the digital cameras may be processed to generate 2-dimensional or 3-dimensional tomographic background-oriented schlieren (BOS) images having features corresponding to pressure gradients of the substance. Alternatively, the data may be processed to provide 2-dimensional shadowgraphs or photogrammetry images.
The method may include positioning imaging units around a wind tunnel having a plurality of windows comprising light-transmitting material. The coaxial beams may pass through the windows into a gas or other substance in the test space.
The method may include activating the light sources of each imaging unit at substantially the same time to provide simultaneous pulses of light. The method may also include actuating the digital cameras of each imaging unit at substantially the same time, whereby the digital cameras capture light reflected back from the background patterns.
One or more embodiments of the present disclosure may optionally provide one or more of the following benefits or advantages:
-
- Co-axial illumination minimizes reflections from windows in a wind tunnel.
- Co-axial illumination minimizes the presence of shadows cast by a wind tunnel model on background panels.
- Co-axial illumination provides for a high amount of returned light to the camera when using a retro-reflective background.
- Use of a condensing lens with a diffuser enlarges the apparent size of the light source such that it is generally of the same scale as the lens entrance aperture to minimize shadowgraph effects if required.
- The compact nature of the imaging units allows for measurements in wind tunnel facilities with severe working space restrictions.
These and other features of various embodiments will be further understood and appreciated by those skilled in the art by reference to the following specification, claims, and appended drawings.
The patent or application file contains at least one drawing executed in color. Copies of this patent or patent application publication with color drawing(s) will be provided by the Office upon request and payment of the necessary fee.
For purposes of description herein, the terms “upper,” “lower,” “right,” “left,” “rear,” “front,” “vertical,” “horizontal,” and derivatives thereof shall relate to the invention as oriented in
A wind tunnel 1 (
Example wind tunnel 1 includes a pair of side windows 6 and a plurality of round windows in the form of portholes 7. Wind tunnel 1 may also include a window 6H in ceiling 3 and a window 6A in floor 4. The side windows 6 and portholes 7 may include light-transmitting material (e.g., acrylic polymer, glass, etc.) covering openings of the windows 6 and portholes 7 to thereby prevent flow of air from the test space 5 to an exterior space such as plenum 8 (see, e.g.,
Imaging units 10A-10H may be positioned in plenum 8 adjacent one or more windows and/or portholes to collect image data of gasses or other material in test space 5 during operation of wind tunnel 1. Each imaging unit 10A-10H may comprise on imaging unit 10 (
Referring again to
With reference to
Light source 24 preferably comprises one LED in accordance with a particular embodiment disclosed herein. However, a plurality of LEDs may also be utilized. As discussed in more detail below, light from light source 24 may be an LED light source and is coupled onto optical axis 13 of camera 20 to produce a beam of light 26 that is generally coaxial with optical axis 13 of camera 20 to thereby provide light for optical imaging without requiring lights that are offset from optical axis 13. In general, if a light source is offset from optical axis 13, the light may reflect from the light-transmitting material covering the windows 6 and portholes 7, which interferes with the imaging process. A condenser-diffuser lens 25 may be utilized, and comprise virtually any suitable lens. In a non-limiting embodiment, lens 25 may comprise a 1500 grit aspheric lens (e.g., Thorlabs, ACL2520U-DG15-A). Light source 24 may comprise virtually any device (e.g., an LED) that is capable of producing a high intensity pulse of light for a short period of time (e.g., CBT-120-R-C11-HK101, commercially available from Luminous Devices, Inc.). It will be understood that the present disclosure is not limited to those specific components. For example, lens 25 may comprise a fine grit diffuser and aspheric condenser lens or other suitable components. Although light source 24 may comprise an LED, any suitable light source may be utilized.
The imaging unit 10 further includes a controller, such as PCB-based LED driver circuit 30 which may be mounted to the housing 23. Imaging unit 10 may also include a protective cover 28 that is secured to the housing 23 by standoffs 29. Driver circuit 30 may be configured to account for differences in actuation lag time of camera 20 relative to LED light source 24. For example, camera 20 may have a lag time upon time receiving an actuation signal that is greater than a lag time of the LED light source 24, and driver circuit 30 may be configured to generate an actuation signal to the camera 20 before generating an actuation signal to the LED light source 24 such that the camera is actuated to generate an image during a light pulse from LED light source 24. The PCB 24A and LED light source 24 may (optionally) be directly connected to the driver circuit 30 with spade connectors to minimize the path length between the LED light source 24 and the power supply of driver circuit 30. This may facilitate over-driving LED light source 24 with high electrical current and short pulse duration as may be required in some applications. Light from the LED light source 24 is diffused by the condenser-diffuser lens 25 to minimize the appearance of patterns that may be present on the emitting surface of the LED light source 24. The condenser-diffuser lens 25 also increases the apparent size of the LED light source 24 to minimize any potential shadowgraph effects. However, it will be understood that the condenser-diffuser lens 25 is optional. The light 26 is coupled onto the optical axis 13 of the camera 20, and the light reflects off the background pattern (e.g., surfaces 18 of panels 17,
The imaging unit 10 may form a compact rigid structure that can be adjustably connected to a base 36 by a support assembly 35. Support assembly 35 includes first and second shafts 37 and 38, and clamping brackets 39 and 40 that can be clamped to the shafts 37 and 38 by tightening threaded connectors 41 and 42. Specifically, clamping bracket 39 permits translation along axis “A1” of second shaft 38, and also permits rotation “R1” about axis A1, and second clamping bracket 40 permits longitudinal adjustment along axis “A2” and rotational adjustment “R2” about axis “A2” of first shaft 37. An adapter plate 43 (see also
In the depicted embodiment, to enable focus adjustments of the lens, the screw for the beam splitter device (e.g., cube 22) is loosened and slides along a slot 43A (
Each camera 20 may have two connections, namely, an Ethernet cable 51 (
Commercially available software (e.g., Basler Pylon Viewer) may be used to acquire data synchronously for all cameras 20 in the system. Trigger cables 52 from each camera 20 are connected to a trigger/power board 54, which acts as a central hub for all triggering signals. A function generator 55 is also connected to the trigger board 54, as well as to a BNC trigger input for the driver circuit 30. Function generator 55 triggers the LED light sources 24, controls the pulse duration of the LED light sources 24 and controls the phase delay between the camera trigger and the LED trigger. As noted above, a delay between the LED and camera trigger may be required if there is an inherent delay in the camera exposure start time after receiving a trigger (actuation signal) whereas the response of the LED light source 24 may be substantially instantaneous. A single trigger coaxial cable from function generator 55 may be connected to a first camera of a system (e.g.,
The imaging units 10 (
The imaging units 10 may be configured to provide low-speed acquisition (on the order of a few Hz), if time resolution is not a priority. The imaging units 10 are preferably configured to be able to withstand low pressures and high temperatures in plenum 8 during pump-down and operation of wind tunnel 1. The imaging units 10 may be configured to provide short exposure to “freeze” fluid flow up to Mach 1.4 or higher Mach numbers (e.g., Mach 6-10). A controller, such as driver circuit 30 (
During operation of wind tunnel 1, air or other fluid 11 flows through interior test space 5 around a model 34 (
Surfaces 18A-18H of background panels 17A-17H, respectfully, may include a uniform density and distribution of retroreflective background dot patterns based on the field of view 15 of the cameras 20 of imaging units 10, and the distance “Dl” (
According to a non-limiting embodiment, a dot pattern was formed on surfaces 18A-18H by spraying flat-black spray paint onto the surface. In particular, the nozzle of the spray paint can was enlarged from its original diameter, the background panels 17A-17H were placed on the floor, and the can was held upright with the nozzle depressed slightly until a stream of paint particles were ejected and fell onto the background material. This combination of an enlarged nozzle diameter and the light nozzle pressure resulted in generally repeated background patterns with some variation in dot size and distribution period. In the illustrated example, the sprayed backgrounds were then applied to flat panels, utilizing the adhesive backing of the high gain reflective shielding, which panels were cut to the appropriate size for each background 17A-17H. It will be understood that this is merely one example of suitable background configuration, and a wide range of backgrounds may be utilized.
Prior to use, the imaging units 10 may be calibrated utilizing a calibration plate (not shown). Calibration of BOS systems is generally known, and a detailed description of the calibration process is, therefore, not believed to be required. In use, as fluid 11 flows through the interior test space 5, the imaging units 10 are actuated to capture images, and the images can be processed utilizing known software to provide tomographic reconstruction. An example of software that may be utilized to process the image data from the imaging units 10 is DaVis Version 10.0.5 (or 10.1.1) software commercially available from LaVision of Ypsilanti, Mich. It will be understood that virtually any suitable program may be utilized.
With further reference to
With reference to
With further reference to
With further reference to
The cameras 20 and/or 120 may optionally comprise small CMOS cameras fitted with C-mount lenses, and light from a high-intensity light source (e.g., LEDs 24, 124) may pass through a lens 25, 125 that diffuses and collimates the LED output. This light is coupled onto the camera's optical axis 13, 113 using a suitable beam-splitting device, such as a 50/50 beam-splitting prism. The illumination components, beam-splitter, and camera/imaging components optionally comprise a single, rigid imaging unit. The use of a collimating/diffusing lens to condition the LED light output provides for an illumination source that is of similar diameter to the imaging lens of the camera 20, 120. This reduces or eliminates shadows that could otherwise be projected onto the subject plane as a result of refractive index variations in the imaged volume. By coupling the light from the LED unit 24, 124 onto the camera's optical axis 13, 113, reflections from windows (which are often present in wind tunnel facilities and allow direct views of the test section) can be minimized or eliminated if the camera is placed at an angle (e.g., 8-10 degrees) of incidence relative to the surface of the window.
With further reference to
The imaging system of the present disclosure may comprise a compact unit with a built-in illumination source that can be positioned in a plenum or other space behind a viewing port/window of a typical wind tunnel. The camera may comprise a compact CMOS camera that acquires images with sufficient resolution and bit-depth to provide high-quality BOS data for a 3-D tomographic BOS reconstruction. It will be understood that the camera data may also be utilized for 2-dimensional BOS flow visualization photogrammetry, machine vision, shadowgraphs, or other applications. The support structure (housing) of the imaging units is preferably constructed so that the output from a small LED light source may be conditioned using a diffusing lens to increase the apparent size of the light source such that it is similar in size to the diameter of the main lens of the camera or to minimize shadow effects while also concentrating the light onto the subject. The output of the light source is preferably co-linear with the optical axis of the camera due the beam-splitting device. Because the light from the light source is co-linear with the optical axis of the camera, the amount of light returned to the camera is increased when imaging a retroreflective background target in the image plane, while limiting the appearance of hard shadows formed by objects (e.g., wind tunnel models) that occlude the object plane.
It is to be understood that variations and modifications can be made on the aforementioned structure without departing from the concepts of the present disclosure, and further it is to be understood that such concepts are intended to be covered by the following claims unless these claims by their language expressly state otherwise.
Claims
1. An imaging system comprising:
- an imaging lens;
- an optical sensor defining an optical axis;
- a light source;
- an optical beam splitter; and
- a diffusing lens configured to perform at least one of diffusion and collimation of light from the light source and direct light exiting the diffusing lens to the optical beam splitter;
- wherein the optical beam splitter is configured to direct light from the diffusing lens along the optical axis of the optical sensor.
2. The imaging system of claim 1, wherein:
- the light directed along the optical axis by the optical beam splitter has a minimum cross-sectional size that is about equal to a size of the diffusing lens.
3. The imaging system of claim 2, wherein:
- the optical sensor comprises a digital camera including an imaging lens defining a lens diameter; and
- the light directed along the optical axis has a minimum diameter that is at least as large as the lens diameter.
4. The imaging system of claim 1, wherein:
- The optical beam splitter comprises a 50/50 beam-splitting cube.
5. The imaging system of claim 1, wherein:
- the light source comprises one or more LEDs that are configured to produce a short-duration, high-intensity illumination pulse.
6. The imaging system of claim 5, wherein:
- the LED light source is configured to produce an illumination pulse of less than about 10 microseconds.
7. The imaging system of claim 1, wherein:
- the optical sensor, the light source, the optical beam splitter, and the diffusing lens are rigidly interconnected to form an imaging unit.
8. The imaging system of claim 7, wherein the imaging unit is a plurality of imaging units, each imaging unit of the plurality of imaging units including an optical sensor, a light source, and an optical beam splitter, wherein the optical axes of the imaging units are radially spaced about a test region having a fluid disposed therein; and
- the system further comprising:
- at least one background pattern aligned with each optical axis, whereby at least some light from the light source of each imaging unit is reflected back to the optical sensor of each imaging unit, whereby the optical sensors capture images of the background patterns, wherein the images from each imaging unit comprises a 2-dimensional BOS image, whereby the synchronous images can be processed to provide a tomographic reconstruction.
9. The imaging system of claim 8, including:
- a controller configured to simultaneously actuate the optical sensors and light sources of each imaging unit.
10. The imaging system of claim 9, wherein:
- the optical sensors comprise digital cameras;
- the light sources comprise LED light sources; and
- the controller comprises electrical circuitry that is configured to generate a camera actuation signal to the digital camera followed by an actuation signal to the LED light sources whereby the electrical circuitry compensates for an actuation time delay of the digital camera relative to the LED light sources and causes the LED light sources to generate a pulse of light that is reflected back to the digital cameras when the digital cameras are actuated.
11. The imaging system of claim 8, wherein:
- the optical sensors comprise digital cameras;
- the light sources comprise LED light sources;
- each imaging unit includes a housing, and the digital camera, LED light source, and optical beam splitter of each imaging unit are supported by the respective housing; and
- each imaging unit further including an adjustable bracket having a first part connected to the housing, and a base, wherein the first part is adjustably connected to the base, whereby the first part can be rotated and translated relative to the base about three axes to a selected position.
12. The imaging system of claim 8, wherein the test region is a test region of a wind tunnel having side walls disposed about an interior space that includes the test region, the side walls including light-transmittal material forming windows, wherein the optical axis of each imaging unit is aligned with a window, and wherein the imaging units are disposed outside of the wind tunnel to capture images of material in the test region.
13. The imaging system of claim 1, wherein:
- the optical sensor comprises a CMOS device;
- the light source comprises a green or red LED; and
- the optical beam splitter comprises a 50/50 beam-splitting plate.
14. An imaging system comprising:
- a plurality of imaging units, each imaging unit including: a digital camera defining an optical axis; a light source configured to generate light traveling transverse relative to the optical axis of the digital camera; an optical beam splitter configured to couple light from the light source and direct a coaxial beam of light along the optical axis of the digital camera; a substantially rigid structure interconnecting the digital camera, the light source, and the optical beam splitter; and
- a controller configured to actuate the digital camera and the light source of the units in a substantially simultaneous manner;
- wherein the imaging units are disposed about a test region with the optical axes of the digital cameras extending through the test region.
15. The imaging system of claim 14, wherein:
- each imaging unit includes an aperture positioned between the light source and the optical beam splitter to block a portion of the light from the light source whereby light traveling through the aperture reaches the optical beam splitter and the coaxial beam of light is suitable for producing a shadowgraph.
16. The imaging system of claim 15, wherein:
- each imaging unit includes a diffusing lens positioned between the light source and the optical beam splitter whereby light from the light source passes through the aperture and the diffusing lens.
17. The imaging system of claim 14, wherein:
- a substantially rigid structure of each imaging unit comprises a housing and an adjustable mount that permits three-axis rotation and three-axis translation of the digital camera relative to a base.
18. A method of generating images, the method comprising:
- providing a plurality of imaging units, each imaging unit including a digital camera defining an optical axis, a light source, and an optical beam splitter;
- using the optical beam splitter to cause light from each light source to be coupled onto the optical axis of each digital camera in the form of a coaxial beam;
- positioning the imaging units about a test space;
- causing the coaxial beams of the imaging units to pass through a substance in the test space;
- causing the coaxial beams to reflect back to the digital cameras from background patterns; and
- processing data from the digital cameras to generate tomographic background-oriented schlieren images having features corresponding to pressure gradients of the substance.
19. The method of claim 18, including:
- positioning the imaging units around a wind tunnel having a plurality of windows comprising light transmitting material; and
- causing the coaxial beams to pass through the windows.
20. The method of claim 18, including:
- activating the light sources of each imaging unit at substantially the same time to provide simultaneous pulses of light; and
- actuating the digital cameras of each imaging unit at substantially the same time, whereby the digital cameras capture light reflected back from the background patterns.
Type: Application
Filed: Aug 24, 2020
Publication Date: Aug 18, 2022
Patent Grant number: 11503222
Inventors: Brett F. Bathel (Yorktown, VA), Stephen B. Jones (Newport News, VA), Joshua M. Weisberger (Newport News, VA)
Application Number: 17/001,037