The invention is a system and method to measure oil content in water utilizing the fluorescence of oil emitted under excitation by laser. Oil and water mixture is transferred through the system to a measurement section in a microscope, which produces high resolution 3-dimensional images of the oil and water mixture with the fluorescence. The images are analyzed to calculate the amount of oil in water and oil droplets distribution. The image is also analyzed to distinguish oil coated solids from oil droplets, and to calculate the sizes and volumes of the solids.

An arrangement for use in illuminating a sample in SPIM microscopy includes an illumination objective configured to receive and focus a light strip or a quasi-light strip. The quasi-light strip is made up of a light bundle continuously moved back and forth in a light-strip plane. A deflection apparatus is configured to deflect the light strip or the quasi-light strip, after the light strip or the quasi-light strip has passed through the illumination objective, in such a way that the light strip or the quasi-light strip propagates at an angle different from zero degrees with respect to an optical axis of the illumination objective. The illumination objective and the deflection apparatus are arranged movably relative to one another.

The present invention provides a sample inspection and quantitative imaging system and method for performing off-axis interferometric imaging while enabling to record off-axis holograms in an extended field of view (FOV) than possible using a given camera and imaging setup, and thus to enlarge (e.g. double, triple, or even more than this) the interferometric FOV, without changing the imaging parameters, such as the magnification and the resolution.

The present invention provides a sample inspection and quantitative imaging system and method for performing off-axis interferometric imaging while enabling to record off-axis holograms in an extended field of view (FOV) than possible using a given camera and imaging setup, and thus to enlarge (e.g. double, triple, or even more than this) the interferometric FOV, without changing the imaging parameters, such as the magnification and the resolution.

Object interference in biological samples generated by lateral shearing interference microscopes is addressed by a shearing microscope slide comprising a periodic structure having alternating reference and sample regions. In some embodiments, the reference regions are configured to provide references that remove sample overlap in a sheared microscopic measurement. A system for generating sheared microscopic measurements is also provided that comprises an inlet configured to receive a sample material, an outlet configured to release a portion of the sample material, and a periodic structure having a plurality of interleaved reference and sample channels. In some cases, the sample channels are configured to accommodate a flow of sample material from the inlet to the outlet and the reference channels are configured to provide references that remove sample overlap in a sheared microscopic measurement.

Object interference in biological samples generated by lateral shearing interference microscopes is addressed by a shearing microscope slide comprising a periodic structure having alternating reference and sample regions. In some embodiments, the reference regions are configured to provide references that remove sample overlap in a sheared microscopic measurement. A system for generating sheared microscopic measurements is also provided that comprises an inlet configured to receive a sample material, an outlet configured to release a portion of the sample material, and a periodic structure having a plurality of interleaved reference and sample channels. In some cases, the sample channels are configured to accommodate a flow of sample material from the inlet to the outlet and the reference channels are configured to provide references that remove sample overlap in a sheared microscopic measurement.

The invention relates to a method for determining the thickness and refractive index of a layer (6) on a substrate (26). The layer (6) having a layer boundary surface (30) facing the substrate (26) and a layer top side (28) facing away from the substrate (26). In said method, the following steps are performed; imaging the layer (6), by confocal microscopy, along an optical axis (8), determining a point spread function resolved along the optical axis (8) al the layer boundary surface (30) and the layer lop side (28), determining an apparent thickness of the layer at a lateral point of the layer from the distance between two maxima of the point spread function, determining the widening of a maximum that the point spread function has at the layer boundary surface (30) relative to the width of the same maximum that the point spread function has at the layer top side (28), at the lateral point, and determining the thickness and refractive index of the layer (6) at the lateral point from the apparent thickness and the widening.

The invention relates to a method for determining the thickness and refractive index of a layer (6) on a substrate (26). The layer (6) having a layer boundary surface (30) facing the substrate (26) and a layer top side (28) facing away from the substrate (26). In said method, the following steps are performed; imaging the layer (6), by confocal microscopy, along an optical axis (8), determining a point spread function resolved along the optical axis (8) al the layer boundary surface (30) and the layer lop side (28), determining an apparent thickness of the layer at a lateral point of the layer from the distance between two maxima of the point spread function, determining the widening of a maximum that the point spread function has at the layer boundary surface (30) relative to the width of the same maximum that the point spread function has at the layer top side (28), at the lateral point, and determining the thickness and refractive index of the layer (6) at the lateral point from the apparent thickness and the widening.

A polarization holographic microscope system is disclosed. The polarization holographic microscope system can acquire a birefringence image and a three-dimensional phase image with high sensitivity by aperture synthesis of sample beams at various angles, and a sample image acquisition method using the microscope system.

A polarization holographic microscope system is disclosed. The polarization holographic microscope system can acquire a birefringence image and a three-dimensional phase image with high sensitivity by aperture synthesis of sample beams at various angles, and a sample image acquisition method using the microscope system.