Abstract: The invention concerns the field of microelectronics and relates to a three-dimensional component which, for example as a sensor, measures the direction of a property in a vector field. The object of the present solution is to specify a three-dimensional component that is capable of measuring and/or generating vector fields in multiple directions and/or simultaneously with low space requirements. The object is attained with a three-dimensional component for the uni-, bi-, tri- or multi-directional measurement and/or generation of vector fields, in which component at least one element made of material systems in present on a three-dimensional carrier made of at least one carrier material, which element measures and/or generates at least one vector field in at least one direction in the spatial position of the element on, against and/or in the carrier.

Abstract: Three-dimensional micro devices usable as electromagnetic and magnetomechanical energy converters, as micromagnetic motors or generators, and methods for their production. The three-dimensional micro devices exhibit high efficiency even at dimensions on the microscale and below, and the method for production, as well as mass production, is simple and economical. Moreover, the three-dimensional micro devices at least include one three-dimensional device produced using roll-up technology. This three-dimensional device includes all functional and structural components for full functionality. At least one functional or structural component is an element that is at least partially freely movable at least partially within a surrounding element and is arranged such that it can be rotated at least around one of its axes.

Abstract: In the field of microelectronics, this concerns a method that can be used to determine the position of objects with improved resolution. The subject of the present invention is to specify a method that is used to determine the position of the objects with high accuracy. The method is achieved according to the invention wherein objects in a medium either a signal modulated with a code is sent from the component to the object, converted there into a signal modulated with another code and sent to a component, or a non-code-modulated signal is transmitted from the component to the object, converted there into a signal modulated with a code and sent to a component, or an object generates a signal modulated with a code and sends it to a component, and the noise component of the signal is removed.

Abstract: The invention concerns the field of microelectronics and relates to a three-dimensional component which, for example as a sensor, measures the direction of a property in a vector field. The object of the present solution is to specify a three-dimensional component that is capable of measuring and/or generating vector fields in multiple directions and/or simultaneously with low space requirements. The object is attained with a three-dimensional component for the uni-, bi-, tri- or multi-directional measurement and/or generation of vector fields, in which component at least one element made of material systems in present on a three-dimensional carrier made of at least one carrier material, which element measures and/or generates at least one vector field in at least one direction in the spatial position of the element on, against and/or in the carrier.

Abstract: The present invention relates to the fields of physics, material sciences and micro and nano electronics, and concerns a method for producing a rolled-up electrical or electronic component, as can be used for example as a capacitor, or in aerials. The object of the present invention is to provide a low-cost, environmentally friendly and time-saving method for producing a rolled-up electrical or electronic component with many windings. The object is achieved by a method for producing a rolled-up component in which at least two functional and insulating layers, alternately arranged fully or partially over one another, are applied to a substrate with a sacrificial layer, wherein at least the functional or insulating layer that is arranged directly on the sacrificial layer has a perforation, at least on the two sides that are arranged substantially parallel to the rolling direction.

Abstract: Three-dimensional micro devices usable as electromagnetic and magnetomechanical energy converters, as micromagnetic motors or generators, and methods for their production. The three-dimensional micro devices exhibit high efficiency even at dimensions on the microscale and below, and the method for production, as well as mass production, is simple and economical. Moreover, the three-dimensional micro devices at least include one three-dimensional device produced using roll-up technology. This three-dimensional device includes all functional and structural components for full functionality. At least one functional or structural component is an element that is at least partially freely movable at least partially within a surrounding element and is arranged such that it can be rotated at least around one of its axes.

Abstract: The present invention relates to the fields of physics, material sciences and micro and nano electronics, and concerns a method for producing a rolled-up electrical or electronic component, as can be used for example as a capacitor, or in aerials. The object of the present invention is to provide a low-cost, environmentally friendly and time-saving method for producing a rolled-up electrical or electronic component with many windings. The object is achieved by a method for producing a rolled-up component in which at least two functional and insulating layers, alternately arranged fully or partially over one another, are applied to a substrate with a sacrificial layer, wherein at least the functional or insulating layer that is arranged directly on the sacrificial layer has a perforation, at least on the two sides that are arranged substantially parallel to the rolling direction.

Abstract: A method for producing printed magnetic functional elements for resistance sensors and printed magnetic functional elements. The invention refers to the field of electronics and relates to a method for producing resistance sensors, such as can be used, for example, in magnetic data storage for read sensors or in the automobile industry. The disclosure includes a simple and cost-effective production method and to obtain such printed magnetic functional elements with properties that can be adjusted as desire, in which a magnetic material is deposited onto a substrate as a film, is removed from the substrate and divided into several components and these components are applied on a substrate by means of printing technologies. Aspects are also directed to a printed magnetic functional element for resistance sensors of several components of a film, wherein at least 5% of the components of the functional element have a magnetoimpedance effect.

Abstract: A method for producing printed magnetic functional elements for resistance sensors and printed magnetic functional elements. The invention refers to the field of electronics and relates to a method for producing resistance sensors, such as can be used, for example, in magnetic data storage for read sensors or in the automobile industry. The disclosure includes a simple and cost-effective production method and to obtain such printed magnetic functional elements with properties that can be adjusted as desire, in which a magnetic material is deposited onto a substrate as a film, is removed from the substrate and divided into several components and these components are applied on a substrate by means of printing technologies. Aspects are also directed to a printed magnetic functional element for resistance sensors of several components of a film, wherein at least 5% of the components of the functional element have a magnetoimpedance effect.