Abstract: The present disclosure relates generally to methods and systems useful in imaging applications, especially biological imaging applications, and applications in the metrology, atmospheric, scientific and medical fields. In one aspect, the disclosure provides a method of imaging an object, including illuminating the object with incident radiation through one or more adaptive optical elements; receiving transmitted radiation from the object at a photodetector to provide a base image; and performing the following steps one or more times: adjusting the one or more adaptive optical elements, the adjustment including modifying an optical transfer function of the one or more adaptive optical elements, and receiving transmitted radiation from the object at the photodetector to provide an adjusted image; wherein the adjustment and receiving steps are performed until the adjusted image has substantially reduced aberrations compared to the base image.

Abstract: An electrowetting lens cavity for use in an electrowetting lens is formed of a metal such as aluminum, having an inner surface tapering downward to an aperture, and smooth enough to allow lensing. The inner surface may be machined and then polished to a roughness of under 0.1 ?m. The cavity may form a truncated cone, with the aperture diameter significantly smaller than the tapering part of the inner surface. Dielectric and hydrophobic layers may be formed on the surface of the cavity.

Abstract: A microlens array includes a bottom electrode chip, a sidewall electrode chip, and a top glass chip configured to cooperate to define an array of cavities, each one of the array of cavities containing a fluid. The fluid is a mixture of a polar liquid and a non-polar liquid, in contact with one of the array of sidewalls at a contact angle. The bottom electrode chip includes a plurality of electrical contacts. The sidewall electrode chip includes an array of sidewalls, each including an electrode layer and an insulator layer. When a voltage is applied across the fluid contained a cavity via electrical contacts and the electrode layer of the cavity, the contact angle of the fluid with the sidewall is modified, in embodiments without affecting the contact angle of fluid contained in other ones of the plurality of array of cavities.

Abstract: The present disclosure relates generally to methods and systems useful in imaging applications, especially biological imaging applications, and applications in the metrology, atmospheric, scientific and medical fields. In one aspect, the disclosure provides a method of imaging an object, including illuminating the object with incident radiation through one or more adaptive optical elements; receiving transmitted radiation from the object at a photodetector to provide a base image; and performing the following steps one or more times: adjusting the one or more adaptive optical elements, the adjustment including modifying an optical transfer function of the one or more adaptive optical elements, and receiving transmitted radiation from the object at the photodetector to provide an adjusted image; wherein the adjustment and receiving steps are performed until the adjusted image has substantially reduced aberrations compared to the base image.

Abstract: The present disclosure relates generally to methods and systems useful in imaging applications, especially biological imaging applications, and applications in the metrology, atmospheric, scientific and medical fields. In one aspect, the disclosure provides a method of imaging an object, including illuminating the object with incident radiation through one or more adaptive optical elements; receiving transmitted radiation from the object at a photodetector to provide a base image; and performing the following steps one or more times: adjusting the one or more adaptive optical elements, the adjustment including modifying an optical transfer function of the one or more adaptive optical elements, and receiving transmitted radiation from the object at the photodetector to provide an adjusted image; wherein the adjustment and receiving steps are performed until the adjusted image has substantially reduced aberrations compared to the base image.

Abstract: A tunable optical electrowetting element having a liquid-liquid interface shape controlled by an applied voltage. Circuitry for applying a voltage to the electrowetting element is configured to apply a shaped voltage signal comprising a first fast-rising signal combined with a second fast-rising signal. The second signal is selected to damp oscillations in the liquid-liquid interface caused by the first signal.

Abstract: A system for high resolution multiphoton excitation microscopy is described herein. In one embodiment, the system may include an electrowetting on dielectric (EWOD) prism optically coupled to an excitation source, the EWOD prism adapted or configured to: receive a light beam from the excitation source, and project the received light beam onto a sample plane based on a tunable transmission angle of the EWOD prism, and a fluorescence imaging microscope adapted or configured to: receive a fluorescence signal from the sample plane based on the projected light beam, and relay the fluorescence signal from the sample plane to a set of detectors.

Abstract: Wide-angle beam steering using two or more variable lenses to form a small-angle beam steering element, along with a numerical aperture converter and a wide-angle lens. The small-angle beam steering element might comprise either one- or two-dimensional beam steering with tunable liquid lenses.

Abstract: Wide-angle beam steering using two or more variable lenses to form a small-angle beam steering element, along with a numerical aperture converter and a wide-angle lens. The small-angle beam steering element might comprise either one- or two-dimensional beam steering with tunable liquid lenses.

Abstract: The present disclosure relates generally to methods and systems useful in imaging applications, especially biological imaging applications, and applications in the metrology, atmospheric, scientific and medical fields. In one aspect, the disclosure provides a method of imaging an object, including illuminating the object with incident radiation through one or more adaptive optical elements; receiving transmitted radiation from the object at a photodetector to provide a base image; and performing the following steps one or more times: adjusting the one or more adaptive optical elements, the adjustment including modifying an optical transfer function of the one or more adaptive optical elements, and receiving transmitted radiation from the object at the photodetector to provide an adjusted image; wherein the adjustment and receiving steps are performed until the adjusted image has substantially reduced aberrations compared to the base image.

Abstract: A system for high resolution multiphoton excitation microscopy is described herein. In one embodiment, the system may include an electrowetting on dielectric (EWOD) prism optically coupled to an excitation source, the EWOD prism adapted or configured to: receive a light beam from the excitation source, and project the received light beam onto a sample plane based on a tunable transmission angle of the EWOD prism, and a fluorescence imaging microscope adapted or configured to: receive a fluorescence signal from the sample plane based on the projected light beam, and relay the fluorescence signal from the sample plane to a set of detectors.

Abstract: A tunable optical electrowetting element having a liquid-liquid interface shape controlled by an applied voltage. Circuitry for applying a voltage to the electrowetting element is configured to apply a shaped voltage signal comprising a first fast-rising signal combined with a second fast-rising signal. The second signal is selected to damp oscillations in the liquid-liquid interface caused by the first signal.