1. Technical Field
This disclosure generally relates to image acquisition. More particularly, this disclosure relates to devices and methods for lensless compressive image acquisition.
2. Description of the Related Art
Various devices are known for image acquisition. Conventional cameras were, for many years, based on capturing images on film. More recently, devices such as cameras have included digital imaging components. Many contemporary digital image or video devices are configured for acquiring and compressing large amounts of raw image or video data.
One drawback associated with many digital systems is that they require significant computational capabilities. Another potential drawback is that multiple expensive sensors may be required.
According to an embodiment, a lensless compressive imaging device may include a micro mirror array having a plurality of mirror elements that are individually controllable for selectively directing light reflecting from the micro mirror array. A detector detects light reflected from at least one of the mirror elements. A processor provides compressive image information based on the detected light.
According to an embodiment, a lensless compressive image acquisition method includes controlling a plurality of mirror elements of a micro mirror array, respectively, for selectively directing light reflecting from the micro mirror array. Light reflected from at least one of the minor elements is detected. Compressive image information is provided based on the detected light.
Various embodiments and their features will become apparent to those skilled in the art from the following detailed description. The drawings that accompany the detailed description can be briefly described as follows.
At least one detector 24 is associated with the micro minor array 22. The detector 24 is configured for detecting light reflecting from at least one of the minor elements of the micro minor array 22. In one example, the detector 24 is configured for detecting visible light. In another example, the detector 24 is configured for detecting infrared light. In other examples, the detector 24 is configured for detecting non-visible light that is outside of the infrared range of the electromagnetic spectrum. On example embodiment is useful for hyperspectral imaging.
The detector 24 in different embodiments may detect a variety of radiation types that are not visible and, therefore, not typically referred to as light.
The term “light” is used in this description to refer generically to different types of light or radiation within the electromagnetic spectrum without necessarily being limited to visible light. Therefore, the term “light” should be understood to include more than just visible light.
One feature of the example of
A processor 26 is associated with the micro minor array 22 for selectively controlling the orientation of each of the minor elements. The processor 26 includes data storage or has associated data storage with information regarding desired orientations of the mirror elements for different image acquisition situations. In one example, the data storage includes information regarding a plurality of bases that indicate the mirror orientations for a particular image acquisition process. Each basis includes an orientation for each of the minor elements. A plurality of different bases allows for a variety of image acquisition capabilities using the micro minor array 22 and the single sensor 24 without requiring a lens.
The processor 26 is configured for gathering information from the detector 24 based on reflected light detected by the detector 24. The processor 26 provides compressive image information based on the detected light. Known techniques are used in one example for processing and formatting the provided compressive image information.
In some examples, the processor 26 is configured for providing image information or image files. In other examples, the processor 26 is configured to provide information to another processor or device that generates an image.
The example of
In another example, the detectors 24 and 28 are configured similar to each other so that they both are capable of detecting light from within the same range of the electromagnetic spectrum. For example, the detectors 24 and 28 may both be configured for detecting visible light or they both may be configured for detecting infrared light.
One feature of the example of
By selectively controlling the orientation of each of the minor elements according to the different bases used by the processor 26, a variety of sets of image information becomes available. For each basis (i.e., selected orientation of the individual minor elements), each detector will provide a different output. Each detector output can be considered a compressive measurement that is utilized by the processor 26 to generate compressive image information. In other words, each bases used for controlling the micro mirror array 22 provides a compressive measurement from each detector. Each of the individual compressive measurements may be viewed as the detected sum of the reflected light from each mirror element during a particular measurement according to a particular basis.
For devices that include more than one detector, such as the examples of
In some embodiments multiple detectors are configured for detecting the same type of light, which allows for obtaining multiple images based on that type of light simultaneously. In some embodiments the detectors are configured for detecting different types of light, which allows for obtaining multiple images, each of which is based on a different type of light, simultaneously.
In some examples, the relative positions of the micro mirror array 22 and the one or more detectors 24, 28 are adjustable for changing a distance between the micro mirror array and at least one of the detectors. A known linear actuator is included in one example embodiment for selectively altering the distance between the detectors and the micro mirror array. Another example includes the ability to change the position of detectors relative to each other for obtaining different image information in different manners depending on the needs of a particular situation.
Each basis may include a selected number of the mirror elements oriented or tuned for directing reflected light toward a particular sensor. Mirror elements that are oriented for directing reflected light in this manner may be considered to be active or on according to a particular basis. Other mirror elements that do not reflect light toward a particular detector may be considered to be inactive or off according to a particular basis. Of course, some mirror elements may be considered active or on for one of the detectors while, at the same time, be considered inactive or off relative to another of the detectors. In the example of
The number of mirror elements and detectors shown in the illustrations is for description purposes only. Those skilled in the art will realize that various configurations of a micro minor array and various configurations of one or a plurality of detectors may be utilized consistent with the principles of operation described above. The disclosed example embodiments provide an image acquisition device and method that is capable of generating compressive image information based upon at least one of visible light or infrared light.
The preceding description is exemplary rather than limiting in nature. Variations and modifications to the disclosed examples may become apparent to those skilled in the art that do not necessarily depart from the essence of the disclosed embodiments. The scope of legal protection can only be determined by studying the following claims.
This application is a continuation-in-part of co-pending U.S. patent application Ser. No. 13/367,413 which was filed on Feb. 7, 2012.
Number | Date | Country | |
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Parent | 13367413 | Feb 2012 | US |
Child | 13658900 | US |