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    High-resolution super-resolved imaging is achieved using dissimilar lenslets, enabling significant reductions in imaging system track length. This novel approach overcomes limitations of traditional lenslet arrays for advanced optical systems.

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    Area of Science:

    • Optical engineering
    • Imaging systems
    • Metamaterials

    Background:

    • Conventional lens systems can be miniaturized using N×N arrays of identical lenslets, reducing track length.
    • However, this approach is limited to low-resolution imaging applications.

    Purpose of the Study:

    • To demonstrate high-resolution super-resolved imaging using an array of dissimilar lenslets.
    • To achieve significant reductions in imaging system track length without compromising image quality.

    Main Methods:

    • Utilizing an array of dissimilar, freeform lenslets wider than the detector array.
    • Ray-traced design and optimization of a long-wave infrared (LWIR) system.
    • Simulations of image recovery for quality assessment.

    Main Results:

    • A 3×3 array of freeform lenslets provided a fourfold reduction in track length compared to a baseline system.
    • Simulated recovered image quality was comparable to the baseline system.
    • Enabled high-resolution super-resolved imaging with miniaturized optics.

    Conclusions:

    • Arrays of dissimilar lenslets offer a viable method for high-resolution super-resolved imaging.
    • This technique significantly reduces imaging system track length.
    • The approach is suitable for advanced optical systems, including LWIR imaging.