Abstract: An optical component for illuminating a sample region with a periodic light pattern comprises: a first waveguide, a further waveguide and an optical splitter. The optical splitter has an input for receiving light, a first output and a second output. The first waveguide is optically coupled to the first output, to direct the first input light into the sample region in a first direction. The second output is optically coupled to the sample region to direct second input light into the sample region in a second direction. The further waveguide is arranged to receive third input light which is directed into the sample region in a third direction. The first direction, second direction and third direction are different from one another. The first and second input light interferes to form a periodic pattern in the sample region. The optical component may be used for structured illumination microscopy.

Abstract: At least one embodiment relates to an apparatus for super-resolution fluorescence-microscopy imaging of a sample. The apparatus includes an objective lens having a forward field of view, the objective lens being configured to collect light. The apparatus may also include a processing arrangement configured to perform super-resolution fluorescence-microscopy imaging of the sample with the collected light. Further, the apparatus includes a waveguide component located forward of the objective lens and configured to (i) receive light from outside the forward field of view, and (ii) use total internal reflection within the waveguide component to direct excitation light. In addition, the apparatus includes an electronic optical-path control system configured to cause input light of a first wavelength to follow a first optical path corresponding to a first optical mode and also configured to cause input light of the first wavelength to follow a second optical path corresponding to a second optical mode.

Abstract: An optical component for illuminating a sample region with a periodic light pattern comprises: a first waveguide, a further waveguide and an optical splitter. The optical splitter has an input for receiving light, a first output and a second output. The first waveguide is optically coupled to the first output, to direct the first input light into the sample region in a first direction. The second output is optically coupled to the sample region to direct second input light into the sample region in a second direction. The further waveguide is arranged to receive third input light which is directed into the sample region in a third direction. The first direction, second direction and third direction are different from one another. The first and second input light interferes to form a periodic pattern in the sample region. The optical component may be used for structured illumination microscopy.

Abstract: At least one embodiment relates to an apparatus for super-resolution fluorescence-microscopy imaging of a sample. The apparatus includes an objective lens having a forward field of view, the objective lens being configured to collect light. The apparatus may also include a processing arrangement configured to perform super-resolution fluorescence-microscopy imaging of the sample with the collected light. Further, the apparatus includes a waveguide component located forward of the objective lens and configured to (i) receive light from outside the forward field of view, and (ii) use total internal reflection within the waveguide component to direct excitation light. In addition, the apparatus includes an electronic optical-path control system configured to cause input light of a first wavelength to follow a first optical path corresponding to a first optical mode and also configured to cause input light of the first wavelength to follow a second optical path corresponding to a second optical mode.