A system for wirelessly obtaining physiological data from a subject includes a sensor patch and a separate electronics package. The sensor patch is disposed on and adheres to the subject, and includes a first part of a releasable electrical connector. An electronics package includes a second part of the first releasable electrical connector, which is used to physically and electrically connect the electronics package to the sensor patch. The electronics package includes a flexible substrate, with shells set on this substrate. The shells enclose the electronics. The shells are connected by a flexible circuit board. Analog front end circuitry is placed in one shell, while the wireless transceiver is placed in the other shell.

A system for wirelessly obtaining physiological data from a subject includes a sensor patch and a separate electronics package. The sensor patch is disposed on and adheres to the subject, and includes a first part of a releasable electrical connector. An electronics package includes a second part of the first releasable electrical connector, which is used to physically and electrically connect the electronics package to the sensor patch. The electronics package includes a flexible substrate, with shells set on this substrate. The shells enclose the electronics. The shells are connected by a flexible circuit board. Analog front end circuitry is placed in one shell, while the wireless transceiver is placed in the other shell.

The present disclosure describes a common mode rejection (CMR) electrode configuration. A CMR electrode configuration improves the spatial resolution of electrogram recordings by increasing the size of a region of cardiac tissue that contributes to the electrogram recording.

The present disclosure describes a common mode rejection (CMR) electrode configuration. A CMR electrode configuration improves the spatial resolution of electrogram recordings by increasing the size of a region of cardiac tissue that contributes to the electrogram recording.

The embodiments of the present disclosure provide a signal processing circuit and a signal processing method. The signal processing circuit may include a control circuit, a switch circuit, an analog circuit, and at least two signal acquisition circuits. The at least two signal acquisition circuits may be configured to acquire at least two-channel target signals. The switch circuit may be configured to control conduction between the at least two signal acquisition circuits and the analog circuit, so that the target signal acquired by a part of the at least two signal acquisition circuits may be transmitted to the analog circuit at the same time. The analog circuit may be configured to process the received target signal. The control circuit may be configured to receive the processed target signal and sample the processed target signal.

An isolation amplification circuit having an input stage circuitry and a control circuitry stage interconnected through a galvanic isolation barrier. The input stage circuitry includes a first filter network and a second filter network for supplying first and second output signals in response to the application of first and second electrical input signals. The input stage circuitry includes a first feedback path configured for applying a first feedback signal to a common node of the first filter network to close a first feedback loop around the first filter network and a second feedback path configured for applying a second feedback signal to a common node of the second filter network to close a second feedback loop around the second filter network.

A hearing aid includes a plurality of electrode units, where each of the plurality of electrode units includes an electrode configured to provide an electrical stimulation to a user of the hearing aid and/or to measure a bio response signal of the user; a plurality of electrode channel circuits, where each of the plurality of electrode channel circuits includes: an operational amplifier comprising a first input terminal configured to receive the bio response signal and provide an amplified bio response signal, and the operational amplifier includes a first load input; a first DC offset unit configured to reduce the impact of DC offset in the electrode channel circuit of the plurality of electrode channel circuits by receiving a part of the amplified bio response signal and converting it to a feedback current signal which is transmitted to the first load input for providing balanced drain currents in the operational amplifier.

Sensor circuit device for measuring a bio-potential and/or a bio-impedance of a body, including a master circuit, and at least two active bi-electrodes connected to, and remotely powered by, the master circuit via single-wire first connector. The sensor circuit device further includes a single passive current electrode being connected to the master circuit via single-wire second connector. The sensor circuit device cooperates with a biological signal amplifier configured to measure a bio-potential and/or a bio-impedance. Each active bi-electrode is connectable to the biological signal amplifier via the first connector, such that a bio-potential of the body is measurable between the two active bi-electrodes when the active bi-electrodes and the single current electrode are in contact with a surface of the body.

Sensor circuit device for measuring a bio-potential and/or a bio-impedance of a body, including a master circuit, and at least two active bi-electrodes connected to, and remotely powered by, the master circuit via single-wire first connector. The sensor circuit device further includes a single passive current electrode being connected to the master circuit via single-wire second connector. The sensor circuit device cooperates with a biological signal amplifier configured to measure a bio-potential and/or a bio-impedance. Each active bi-electrode is connectable to the biological signal amplifier via the first connector, such that a bio-potential of the body is measurable between the two active bi-electrodes when the active bi-electrodes and the single current electrode are in contact with a surface of the body.

An ambulatory cardiac device for improving a signal to noise profile of an electrocardiogram (ECG) signal of a patient is provided. The ambulatory cardiac device includes a plurality of active ECG electrodes disposed in a plurality of locations about a patient. Each active electrode can include an ECG electrode substrate configured to be in physical contact with skin of the patient, a local biasing substrate proximate to the ECG electrode substrate and configured to be in physical contact with the skin of the patient, and local biasing circuitry configured to provide a local biasing signal into a body of the patient via the local biasing substrate.