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

What is claimed is: 1. An imaging system comprising: an imaging lens; an optical sensor defining an optical axis; a light source; an optical beam splitter; 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 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; 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 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. 3. The imaging system of claim 1 , wherein: The optical beam splitter comprises a 50/50 beam-splitting cube. 4. 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. 5. The imaging system of claim 4 , wherein: the LED light source is configured to produce an illumination pulse of less than about 10 microseconds. 6. 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. 7. The imaging system of claim 6 , 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. 8. The imaging system of claim 7 , including: a controller configured to simultaneously actuate the optical sensors and light sources of each imaging unit. 9. The imaging system of claim 8 , 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. 10. The imaging system of claim 7 , 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. 11. The imaging system of claim 7 , 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. 12. 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. 13. 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. 14. The imaging system of claim 13 , 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. 15. The imaging system of claim 14 , 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. 16. The imaging system of claim 13 , 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. 17. 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. 18. The method of claim 17 , 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. 19. The method of claim 17 , 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.