Abstract: An electromagnetic wave sensor for determining a hydration status of a body tissue in vivo includes an electromagnetic wave transmitter, a waveguide, and an electromagnetic wave receiver. The electromagnetic wave transmitter is configured to emit an electromagnetic wave signal in a frequency range between 1 Hz and 1 THz. The waveguide is coupled to the electromagnetic wave transmitter. The waveguide is adapted to be arranged next to the body tissue such that a fringe field of the electromagnetic wave signal guided by the waveguide penetrates the body tissue. The electromagnetic wave receiver is coupled to the waveguide. The electromagnetic wave receiver is configured to receive the electromagnetic wave signal modified by the body tissue in dependence of a hydration status of the body tissue.

Abstract: An electromagnetic wave sensor for determining an interstitial fluid parameter in vivo comprises an implantable housing, and a sensor component hermetically encapsulated within the implantable housing. The sensor component comprises an electromagnetic wave transmitter unit configured to emit an electromagnetic wave signal in a frequency range between 300 MHz and 3 THz penetrating the implantable housing and penetrating an interstitial fluid probe volume, an electromagnetic wave receiver unit configured to receive the electromagnetic wave signal modified by the interstitial fluid probe volume, and a transceiver unit configured to transmit radio frequency signals related to the electromagnetic wave signal modified by the interstitial fluid probe volume. A system for determining an interstitial fluid parameter in vivo comprises the electromagnetic wave sensor and an external reader.

Abstract: According to various embodiments, a sensor arrangement for particle analysis may include: a base electrode configured to generate an electrical field for particle attraction; a support layer disposed over the base electrode; a sensor array disposed over the support layer and including or formed from a plurality of sensor elements, wherein each sensor element of the plurality of sensor elements is configured to generate or modify an electrical signal in response to a particle at least one of adsorbed to and approaching the sensor element; and an electrical contact structure may include or be formed from a plurality of contact lines, wherein each contact line of the plurality of contact lines is electrically connected to a respective sensor element of the plurality of sensor elements, such that each sensor element of the plurality of sensor elements is addressable via the contact structure.

Abstract: An electromagnetic wave sensor for determining a hydration status of a body tissue in vivo includes an electromagnetic wave transmitter, a waveguide, and an electromagnetic wave receiver. The electromagnetic wave transmitter is configured to emit an electromagnetic wave signal in a frequency range between 1 Hz and 1 THz. The waveguide is coupled to the electromagnetic wave transmitter. The waveguide is adapted to be arranged next to the body tissue such that a fringe field of the electromagnetic wave signal guided by the waveguide penetrates the body tissue. The electromagnetic wave receiver is coupled to the waveguide. The electromagnetic wave receiver is configured to receive the electromagnetic wave signal modified by the body tissue in dependence of a hydration status of the body tissue.

Abstract: A communication arrangement may include a communication device, which may include an application processor, a mobile radio circuit, and a near-field communication (NFC) circuit configured according to an NFC technology for transmission of data and energy for operating a circuit external to the communication device. The arrangement may include a flexible carrier mounted detachably on the communication device. The carrier may include a radio circuit, an NFC circuit configured according to an NFC technology, a circuit coupled to the NFC circuit and the radio circuit, which is configured to be operated with energy which is received by means of the NFC circuit according to the NFC technology, the circuit configured for converting data coded in accordance with the NFC technology into data coded in accordance with the radio technology, or for converting data coded in accordance with the radio technology into data coded in accordance with the NFC technology.

Abstract: According to various embodiments, a sensor arrangement for particle analysis may include: a base electrode configured to generate an electrical field for particle attraction; a support layer disposed over the base electrode; a sensor array disposed over the support layer and including or formed from a plurality of sensor elements, wherein each sensor element of the plurality of sensor elements is configured to generate or modify an electrical signal in response to a particle at least one of adsorbed to and approaching the sensor element; and an electrical contact structure may include or be formed from a plurality of contact lines, wherein each contact line of the plurality of contact lines is electrically connected to a respective sensor element of the plurality of sensor elements, such that each sensor element of the plurality of sensor elements is addressable via the contact structure.

Abstract: An electromagnetic wave sensor for determining an interstitial fluid parameter in vivo comprises an implantable housing, and a sensor component hermetically encapsulated within the implantable housing. The sensor component comprises an electromagnetic wave transmitter unit configured to emit an electromagnetic wave signal in a frequency range between 300 MHz and 3 THz penetrating the implantable housing and penetrating an interstitial fluid probe volume, an electromagnetic wave receiver unit configured to receive the electromagnetic wave signal modified by the interstitial fluid probe volume, and a transceiver unit con-figured to transmit radio frequency signals related to the electromagnetic wave signal modified by the interstitial fluid probe volume. A system for determining an interstitial fluid parameter in vivo comprises the electromagnetic wave sensor and an external reader.

Abstract: A communication arrangement may include a communication device, which may include an application processor, a mobile radio circuit, and a near-field communication (NFC) circuit configured according to an NFC technology for transmission of data and energy for operating a circuit external to the communication device. The arrangement may include a flexible carrier mounted detachably on the communication device. The carrier may include a radio circuit, an NFC circuit configured according to an NFC technology, a circuit coupled to the NFC circuit and the radio circuit, which is configured to be operated with energy which is received by means of the NFC circuit according to the NFC technology, the circuit configured for converting data coded in accordance with the NFC technology into data coded in accordance with the radio technology, or for converting data coded in accordance with the radio technology into data coded in accordance with the NFC technology.

Abstract: A mounting method for a semiconductor component. The method includes application of solder material to the semiconductor component, application of at least one contact/mounting element made of semiconductor material and/or metal and/or insulator material to the solder material, heating of at least one part of the semiconductor component to a temperature lying above the melting point of the solder material by impressing an electrical power into the semiconductor component, as a result of which corresponding soldering connections arise between the semiconductor component and the at least one contact/mounting element, and cooling of the connection complex that comprises the semiconductor component and at least one contact/mounting element and was produced in the preceding step.

Abstract: A mounting method for a semiconductor component. The method includes application of solder material to the semiconductor component, application of at least one contact/mounting element made of semiconductor material and/or metal and/or insulator material to the solder material, heating of at least one part of the semiconductor component to a temperature lying above the melting point of the solder material by impressing an electrical power into the semiconductor component, as a result of which corresponding soldering connections arise between the semiconductor component and the at least one contact/mounting element, and cooling of the connection complex that comprises the semiconductor component and at least one contact/mounting element and was produced in the preceding step.