Abstract: multi-aperture system for foveated imaging as well as to a corresponding multi-aperture system. The method comprises the steps of: providing an image sensor; and forming, by means of a 3D-printing technique, at least two imaging elements directly on the image sensor such that the imaging elements have a common focal plane located on the image sensor and each imaging element has a different focal length and field of view.

Abstract: The invention relates to a method and a device for producing at least one microstructure (5) on an axial end (1a) of an optical fiber (1). The method comprises the following steps: —providing (S10) the optical fiber (1); —wetting (S20) the axial end (1a) of the optical fiber (1) with photoresist (2); —orienting (S30) the optical fiber (1) and a writing beam of a 3D printer with respect to one another; —forming (S40) the at least one microstructure (5) by exposing the photoresist (2) to light with the aid of the 3D printer.

Abstract: The present invention relates to a method for manufacturing an optical element (100) having at least one functional region using a 3D-printer, comprising the steps: forming a three-dimensional structure (50) of the optical element (100) using a 3D-printer such that the three-dimensional structure (100) has at least one microfluidic cavity (4) for receiving a functional substance (6); and filling the at least one microfluidic cavity (4) with the functional substance (6) for forming the at least one functional region. In addition, the invention relates to a device for manufacturing an optical element (100) as well as a use of the device.

Abstract: multi-aperture system for foveated imaging as well as to a corresponding multi-aperture system. The method comprises the steps of: providing an image sensor; and forming, by means of a 3D-printing technique, at least two imaging elements directly on the image sensor such that the imaging elements have a common focal plane located on the image sensor and each imaging element has a different focal length and field of view.

Abstract: The invention relates to a method and a device for producing at least one microstructure (5) on an axial end (1a) of an optical fiber (1). The method comprises the following steps: —providing (S10) the optical fiber (1); —wetting (S20) the axial end (1a) of the optical fiber (1) with photoresist (2); —orienting (S30) the optical fiber (1) and a writing beam of a 3D printer with respect to one another; —forming (S40) the at least one microstructure (5) by exposing the photoresist (2) to light with the aid of the 3D printer.

Abstract: The present invention relates to a method for connecting a solid core optical fiber (2) with another optical fiber (20), wherein the solid core optical fiber (2) comprises a joining device (10), which is created on one axial end of the solid core optical fiber (2) using a 3D printer and wherein the other optical fiber (20) is incorporated in the joining device (10) via an axial end of the other optical fiber (20), which is thus connected with the solid core optical fiber (2). In addition, the invention relates to a solid core optical fiber (2) with a joining device (10) created by a 3D-printer, and the relevant use of a 3D printer.

Abstract: The present invention relates to a method for manufacturing an optical element (100) having at least one functional region using a 3D-printer, comprising the steps: forming a three-dimensional structure (50) of the optical element (100) using a 3D-printer such that the three-dimensional structure (100) has at least one microfluidic cavity (4) for receiving a functional substance (6); and filling the at least one microfluidic cavity (4) with the functional substance (6) for forming the at least one functional region. In addition, the invention relates to a device for manufacturing an optical element (100) as well as a use of the device.

Abstract: The present invention relates to a method for connecting a solid core optical fiber (2) with another optical fiber (20), wherein the solid core optical fiber (2) comprises a joining device (10), which is created on one axial end of the solid core optical fiber (2) using a 3D printer and wherein the other optical fiber (20) is incorporated in the joining device (10) via an axial end of the other optical fiber (20), which is thus connected with the solid core optical fiber (2). In addition, the invention relates to a solid core optical fiber (2) with a joining device (10) created by a 3D-printer, and the relevant use of a 3D printer.