A textile electronic device configured to be connected to a conductive zone of a textile, the device including: an electronic circuit; at least a first mechanical and electrical connection means configured to be connected to the conductive zone of a textile; a textile substrate having at least a second electrical connection means, the at least one second electrical connection means being electrically connected to the electronic circuit and to the at least one first mechanical and electrical connection means; and a flexible envelope totally or partially including said electronic circuit, the at least one first mechanical and electrical connection means and the textile substrate, the at least one first mechanical connection means and electric being at least partially accessible through the flexible envelope. Also, a manufacturing method of the textile electronic device.

A connection assembly generally comprising a thick conductor piece including a receptacle with an inner wall and a thin conductor piece. The thin conductor piece has a protrusion for insertion into the receptacle. A press-fit element can be inserted into the receptacle with the protrusion arranged in the receptacle between the press-fit element and the thick conductor piece.

The invention proposes a luminous module comprising a flexible printed circuit board. The connection to ground of the electronic circuit accommodated by the printed circuit board is produced without adding fastening parts dedicated to this role. Compared to known prior-art techniques, the invention allows a luminous module to be produced comprising fewer constituent parts and occupying a smaller volume.

Power electronics arrangement including a printed circuit board and at least one power module fastened on the printed circuit board, which has one or more electronic components potted by a potting compound. At least one module connecting point of the power module is electrically contacted with at least one board connecting point of the printed circuit board by an electrically conductive pin. A base section of the pin is fastened on the module connecting point or on the board connecting point, and the end of the pin opposite to the base section is pressed in the installation position into a contacting opening assigned or assignable to the respective other connecting point.

Analyte sensor connectors that connect analyte sensors, e.g., conductive members of analyte sensors, to other devices such as sensor electronics units, e.g., sensor control units, are provided. Also provided are systems that include analyte sensors, analyte sensor connectors, and analyte sensor electronics units, as well as methods of establishing and maintaining connections between analyte sensors and analyte sensor electronics units, and methods of analyte monitoring/detection. Also provided are methods of making analyte sensor connectors and systems that include analyte sensor connectors.

A contact comprising: (a) a contact housing, said contact housing being narrower than a cavity of a connector such that said contact housing is laterally movable within said cavity; (b) an optical interface for receiving a ferrule of a mating connector contact; (c) optoelectrical circuitry optically connected to said optical interface, wherein said optical interface and said optoelectrical circuitry are held rigidly in relation to each other within said contact housing; and (d) an electrical interface electrically connected to said optoelectrical circuitry and configured for electrical connection to a circuit board, wherein said electrical interface comprising at least a flexible cable to provide compliance between said optoelectrical circuitry and said circuit board.

An LED light source module comprises a double-sided circuit board and two rivets electrically connected to both sides of the double-sided circuit board. The rivet includes a nail head, a shank, and a transition section connecting the nail head and the shank. The length of the nail head in a section along the thickness direction of the circuit substrate is greater than the width of the shank, and the transition section is a trapezoid. The short side of the trapezoid is connected to the shank, and the length of the long side of the trapezoid is smaller than the length of the nail head. The nail head is connected to the first wiring layout, and the shank is electrically connected to the second wire pattern by soldering tin. The first and second wiring layouts are electrically connected by the rivet, and the copper plating process with more serious pollution is not used, thereby reducing the cost of pollution control, and the circuit substrate of the lower-level material can be used, and further the competitiveness of the lamp having the LED light source module can be improved.

A circuit package may comprise (1) a substrate, (2) at least one radio frequency (RF) circuit disposed on the substrate, and (3) a plurality of screw holes that are incorporated into the substrate and configured to support mounting the substrate to an enclosure, wherein at least one of the screw holes is further configured to provide at least one supplemental function in connection with the RF circuit. Various other apparatuses, systems, and methods are also disclosed.

Analyte sensor connectors that connect analyte sensors, e.g., conductive members of analyte sensors, to other devices such as sensor electronics units, e.g., sensor control units, are provided. Also provided are systems that include analyte sensors, analyte sensor connectors, and analyte sensor electronics units, as well as methods of establishing and maintaining connections between analyte sensors and analyte sensor electronics units, and methods of analyte monitoring/detection. Also provided are methods of making analyte sensor connectors and systems that include analyte sensor connectors.

Embodiments described herein relate generally to wearable electronic biosensing garments. In some embodiments, an apparatus comprises a biosensing garment and a plurality of electrical connectors that are mechanically fastened to the biosensing garment. A plurality of printed electrodes is disposed on the biosensing garment, each being electrically coupled, via a corresponding conductive pathway, to a corresponding one of the plurality of electrical connectors. The apparatus can further include an elongate member including a conductive member that is coupled to a plurality of elastic members in a curved pattern and that is configured to change from a first configuration to a second configuration as the elongate member stretches. The change from the first configuration to the second configuration can result in a change of inductance of the conductive member.