Cloth electronic product, by which physiological information can be examined through cloth, includes a packaging cloth or a heat melt adhesive film as circuit, at least an electronic component, such as resistors, microprocessors and sensing assembly, etc., at least a transmission line to be connected with the conductive region of electronic component. Method of producing a cloth electronic product includes sewing the electronic component on packaging cloth or heat melt adhesive film after being connected with the transmission line, or connecting electronic component with the transmission line during the process of jointing of transmission or sewing of packaging cloth or heat melt adhesive film, and then sewing the packaging cloth on the clothing cloth or integrating the heat melt adhesive film into the packaging cloth or clothing cloth. Original structure of the heat melt adhesive film cannot be viewed and miniaturization effects can be produced.

Cloth electronic product, by which physiological information can be examined through cloth, includes a packaging cloth or a heat melt adhesive film as circuit, at least an electronic component, such as resistors, microprocessors and sensing assembly, etc., at least a transmission line to be connected with the conductive region of electronic component. Method of producing a cloth electronic product includes sewing the electronic component on packaging cloth or heat melt adhesive film after being connected with the transmission line, or connecting electronic component with the transmission line during the process of jointing of transmission or sewing of packaging cloth or heat melt adhesive film, and then sewing the packaging cloth on the clothing cloth or integrating the heat melt adhesive film into the packaging cloth or clothing cloth. Original structure of the heat melt adhesive film cannot be viewed and miniaturization effects can be produced.

Disclosed herein are apparatuses and methods for treating neurological disorders by electro-stimulation. The apparatus (10) for treating neurological disorders includes at least one electrode (12) implantable in the brain of a patient, and a processing and stimulation device (14) connected to the at least one electrode (12). The processing and stimulation device (14) may include a stimulation module (16) configured to generate a stimulation signal to be sent to the at least one electrode (12), and an acquisition module (20) that measures cerebral activity coming from the brain of the patient. The acquisition module (20) may have a front-end block (27) configured to amplify the potential difference of its input signals (V.sub.1a, V.sub.2a) and to filter a stimulus artifact and may include a multi-stage fully-differential switched capacitor circuit (e.g., an integrated circuit) configured for discrete-time signal processing.

Disclosed herein are apparatuses and methods for treating neurological disorders by electro-stimulation. The apparatus (10) for treating neurological disorders includes at least one electrode (12) implantable in the brain of a patient, and a processing and stimulation device (14) connected to the at least one electrode (12). The processing and stimulation device (14) may include a stimulation module (16) configured to generate a stimulation signal to be sent to the at least one electrode (12), and an acquisition module (20) that measures cerebral activity coming from the brain of the patient. The acquisition module (20) may have a front-end block (27) configured to amplify the potential difference of its input signals (V.sub.1a, V.sub.2a) and to filter a stimulus artifact and may include a multi-stage fully-differential switched capacitor circuit (e.g., an integrated circuit) configured for discrete-time signal processing.

Aspects of the present disclosure are directed to increasing protection against electric shocks when a person is working on an electrical system. In some embodiments, the electrical system includes at least two different circuits and a safety module. An emergency signal input is provided on the safety module, and when an external emergency signal is received via the emergency signal input, the safety module shuts off a configured first circuit the associated switch and at least one further circuit via the associated switch if the safety module still receives the emergency signal at the emergency signal input after a predetermined period of time.

Aspects of the present disclosure are directed to increasing protection against electric shocks when a person is working on an electrical system. In some embodiments, the electrical system includes at least two different circuits and a safety module. An emergency signal input is provided on the safety module, and when an external emergency signal is received via the emergency signal input, the safety module shuts off a configured first circuit the associated switch and at least one further circuit via the associated switch if the safety module still receives the emergency signal at the emergency signal input after a predetermined period of time.

An apparatus and method for improving microcirculation by suppressing and cancelling the negative effects of electromagnetic radiation from cellular phones and computers connected to wireless networks on microcirculation. The apparatus generates frequencies that are synchronized and in opposed amplitudes to the detected electromagnetic radiation frequencies, thereby suppressing and cancelling the negative effects of the electromagnetic radiation frequencies on microcirculation.

An apparatus and method for improving microcirculation by suppressing and cancelling the negative effects of electromagnetic radiation from cellular phones and computers connected to wireless networks on microcirculation. The apparatus generates frequencies that are synchronized and in opposed amplitudes to the detected electromagnetic radiation frequencies, thereby suppressing and cancelling the negative effects of the electromagnetic radiation frequencies on microcirculation.

Disclosed herein are apparatuses and methods for treating neurological disorders by electro-stimulation. The apparatus for treating neurological disorders includes at least one electrode implantable in the brain of a patient, and a processing and stimulation device connected to the at least one electrode. The processing and stimulation device may include a stimulation module configured to generate a stimulation signal to be sent to the at least one electrode, and an acquisition module that measures cerebral activity coming from the brain of the patient. The acquisition module may have a front-end block configured to amplify the potential difference of its input signals (V.sub.1a, V.sub.2a) and to filter a stimulus artifact and may include a multi-stage fully-differential switched capacitor circuit (e.g., an integrated circuit) configured for discrete-time signal processing.

Disclosed herein are apparatuses and methods for treating neurological disorders by electro-stimulation. The apparatus for treating neurological disorders includes at least one electrode implantable in the brain of a patient, and a processing and stimulation device connected to the at least one electrode. The processing and stimulation device may include a stimulation module configured to generate a stimulation signal to be sent to the at least one electrode, and an acquisition module that measures cerebral activity coming from the brain of the patient. The acquisition module may have a front-end block configured to amplify the potential difference of its input signals (V.sub.1a, V.sub.2a) and to filter a stimulus artifact and may include a multi-stage fully-differential switched capacitor circuit (e.g., an integrated circuit) configured for discrete-time signal processing.