A circuit for evaluating measurement signals of at least one sensor with a control circuit. A control signal having a first frequency is generated by a control section of the control circuit and the control signal is applied to the sensor. An electronic evaluation unit is provided for generating an evaluation signal originating from a measurement signal generated by the sensor. The electronic evaluation unit generates an opposing signal having the first frequency and a modifiable phase angle and superposes the opposing signal and the evaluation signal. The signal resulting from the superposition of the opposing signal and the evaluation signal is fed to a synchronous demodulator of the electronic evaluation unit.

A material-discerning sensing device includes an antenna, a capacitive proximity sensor, and a control circuit. The antenna includes multiple conductive loops and is configured to radiate a wireless signal. The antenna defines an interior region devoid of the conductive loops and an exterior region outside the conductive loops. The capacitive proximity sensor includes a conductive pattern provided within the interior region or within a projection of the interior region, as well as a conductive bar. The control circuit is configured to detect a change in a characteristic of an electrical signal from the capacitive sensor. The conductive pattern includes a longitudinal portion, a first plurality of parallel conductors extending away from the longitudinal portion in a first direction and orthogonal to the longitudinal portion, and a second plurality of parallel conductors extending away from the longitudinal portion in a second direction opposite the first direction.

The present invention relates to a composition exhibiting a bile-salt hydrolase activity for its use for the treatment or the prevention of giardiasis, said composition comprising a bile-salt hydrolase (BSH) enzyme, a bacterium able to secrete a BSH, a recombinant host cell able to secrete a BSH, or a combination thereof. The present invention also relates to the use of a composition exhibiting a BSH activity for the treatment or the prevention of giardiasis, and to a pharmaceutical composition or a food composition comprising, as an active principle, a BSH, a lactic acid bacterium able to secrete a BSH, or a recombinant host cell able to secrete a BSH.

A sensor system for the capacitive detection of obstacles, having a capacitive sensor with conductive elements and a control circuit connected thereto. The control circuit has a bridge circuit, and a first end of the bridge branch is connected to a conductive element of the sensor positioned upstream in the direction of detection and a second end of the bridge branch is connected to a conductive element of the sensor positioned downstream in the direction of detection. A control signal is generated by a control section of the control circuit and the sum of impedances of the bridge circuit connected to the first end of the bridge branch is less than the sum of impedances of the bridge circuit connected to the second end of the bridge branch. An electronic evaluation unit is provided to evaluate a voltage difference between the first and second ends of the bridge branch.

Disclosed is a touch panel. The touch panel includes a cover substrate including an active area and an inactive area; a first printing layer on the inactive area; and first and second conductive layers on the first printing layer, wherein the first and second conductive layers extend from a side surface of the first printing layer along a top surface of the first printing layer.

The present invention relates to a composition exhibiting a bile-salt hydrolase activity for its use for the treatment or the prevention of giardiasis, said composition comprising a bile-salt hydrolase (BSH) enzyme, a bacterium able to secrete a BSH, a recombinant host cell able to secrete a BSH, or a combination thereof. The present invention also relates to the use of a composition exhibiting a BSH activity for the treatment or the prevention of giardiasis, and to a pharmaceutical composition or a food composition comprising, as an active principle, a BSH, a lactic acid bacterium able to secrete a BSH, or a recombinant host cell able to secrete a BSH.

An impedance sensing circuit includes three impedance elements and a sensing element arranged in a bridge configuration. A first input terminal is coupled to two of the impedance elements to apply a stimulus signal. In a mutual-sensing mode, a second input terminal is coupled to the third impedance element and the sensing impedance element to apply an opposite phase stimulus signal. The impedance sensing circuit may be configured in a self-sensing mode, in which the opposite phase stimulus signal is decoupled from the third impedance element and the sensing impedance element. At least one of the impedance elements is variable and may be adjusted to balance an offset impedance load on the sensing element.

A material-discerning sensing device includes an antenna, a capacitive proximity sensor, and a control circuit. The antenna includes multiple conductive loops and is configured to radiate a wireless signal. The antenna defines an interior region devoid of the conductive loops and an exterior region outside the conductive loops. The capacitive proximity sensor includes a conductive pattern provided within the interior region or within a projection of the interior region, as well as a conductive bar. The control circuit is configured to detect a change in a characteristic of an electrical signal from the capacitive sensor. The conductive pattern includes a longitudinal portion, a first plurality of parallel conductors extending away from the longitudinal portion in a first direction and orthogonal to the longitudinal portion, and a second plurality of parallel conductors extending away from the longitudinal portion in a second direction opposite the first direction.

A material-discerning sensing device includes an antenna, a capacitive proximity sensor, and a control circuit. The antenna includes multiple conductive loops and is configured to radiate a wireless signal. The antenna defines an interior region devoid of the conductive loops and an exterior region outside the conductive loops. The capacitive proximity sensor includes a conductive pattern provided within the interior region or within a projection of the interior region, as well as a conductive bar. The control circuit is configured to detect a change in a characteristic of an electrical signal from the capacitive sensor. The conductive pattern includes a longitudinal portion, a first plurality of parallel conductors extending away from the longitudinal portion in a first direction and orthogonal to the longitudinal portion, and a second plurality of parallel conductors extending away from the longitudinal portion in a second direction opposite the first direction.

A material-discerning sensing device includes an antenna, a capacitive proximity sensor, and a control circuit. The antenna includes multiple conductive loops and is configured to radiate a wireless signal. The antenna defines an interior region devoid of the conductive loops and an exterior region outside the conductive loops. The capacitive proximity sensor includes a conductive pattern provided within the interior region or within a projection of the interior region, as well as a conductive bar. The control circuit is configured to detect a change in a characteristic of an electrical signal from the capacitive sensor. The conductive pattern includes a longitudinal portion, a first plurality of parallel conductors extending away from the longitudinal portion in a first direction and orthogonal to the longitudinal portion, and a second plurality of parallel conductors extending away from the longitudinal portion in a second direction opposite the first direction.