Method and system for monitoring an internal electrical impedance of a biological object including Internal Thoracic Impedance (ITI) comprising placing two arrays of electrodes on opposite sides of the biological object, wherein each of said two arrays comprise three equally spaced electrodes; imposing an alternating electrical current between pairs of the electrodes and obtaining voltage signals representative of a voltage drop thereon, calculating two values of internal electrical impedance of the biological object corresponding to the uttermost electrodes of said two arrays of electrodes placed on the opposite sides of the biological object.

Method and system for monitoring an internal electrical impedance of a biological object including Internal Thoracic Impedance (ITI) comprising placing two arrays of electrodes on opposite sides of the biological object, wherein each of said two arrays comprise three equally spaced electrodes; imposing an alternating electrical current between pairs of the electrodes and obtaining voltage signals representative of a voltage drop thereon, calculating two values of internal electrical impedance of the biological object corresponding to the uttermost electrodes of said two arrays of electrodes placed on the opposite sides of the biological object.

A medical apparatus includes a therapy component for performing a therapeutic procedure on the patient. The therapy component includes sensing circuitry for sensing electrical signals from one or more sensing electrodes of the therapy component that are placed on and/or in the patient. With the medical apparatus powered on, a determination is made as to when the therapy component is actively engaged in performing the therapeutic procedure on the patient. When the therapy component is actively engaged in performing the therapeutic procedure on the patient, the one or more sensing electrodes of the therapy component are electrically connected to the sensing circuitry. When the therapy component is determined to not be actively engaged in performing the therapeutic procedure on the patient, the one or more sensing electrodes of the therapy component are electrically isolated from the sensing circuitry.

An electrocardiogram (ECG) measurement device for a vehicle is provided. The ECG measurement device includes an impedance compensator that corresponds to an electrode in contact with a body of a driver and configured to compensate an impedance of each of electrode signals received from the electrode. An electrode selector sequentially selects the electrode signals in response to receiving the electrode signals from the electrode. A differential amplifier differentially amplifies the electrode signals. In particular, each electrode signal has the compensated impedance. Additionally, a signal quality evaluator evaluates quality of an ECG signal output from the differential amplifier and a compensation controller then adjusts an impedance compensation value of each of the impedance compensators as a result of evaluating the quality of the ECG signal.

An electrocardiogram (ECG) measurement device for a vehicle is provided. The ECG measurement device includes an impedance compensator that corresponds to an electrode in contact with a body of a driver and configured to compensate an impedance of each of electrode signals received from the electrode. An electrode selector sequentially selects the electrode signals in response to receiving the electrode signals from the electrode. A differential amplifier differentially amplifies the electrode signals. In particular, each electrode signal has the compensated impedance. Additionally, a signal quality evaluator evaluates quality of an ECG signal output from the differential amplifier and a compensation controller then adjusts an impedance compensation value of each of the impedance compensators as a result of evaluating the quality of the ECG signal.

Method and system for monitoring an internal electrical impedance of a biological object including Internal Thoracic Impedance (ITI) comprising placing two arrays of electrodes on opposite sides of the biological object, wherein each of said two arrays comprise three equally spaced electrodes; imposing an alternating electrical current between pairs of the electrodes and obtaining voltage signals representative of a voltage drop thereon, calculating two values of internal electrical impedance of the biological object corresponding to the uttermost electrodes of said two arrays of electrodes placed on the opposite sides of the biological object.

Method and system for monitoring an internal electrical impedance of a biological object including Internal Thoracic Impedance (ITI) comprising placing two arrays of electrodes on opposite sides of the biological object, wherein each of said two arrays comprise three equally spaced electrodes; imposing an alternating electrical current between pairs of the electrodes and obtaining voltage signals representative of a voltage drop thereon, calculating two values of internal electrical impedance of the biological object corresponding to the uttermost electrodes of said two arrays of electrodes placed on the opposite sides of the biological object.

A contact state estimating device includes: a first and a second electrode brought into contact with an object to be measured; a direct current voltage supply unit; a signal switching unit configured to switch a first pathway through which the direct current voltage supply unit supplies direct current voltage to the first electrode and an output signal from the second electrode is output and a second pathway through which the direct current voltage supply unit supplies direct current voltage to the second electrode and an output signal from the first electrode is output to each other; and a contact state estimating unit configured to estimate a contact state of the first electrode or the second electrode with the object, based on the output signal acquired at a timing at which a pulse noise is anticipated to occur in association with switching between the first pathway and the second pathway.

A method and system for multi-electrode monitoring of an internal electrical impendance of a biological object using placing two arrays of electrodes on opposite sides of the biological object, wherein each of said two arrays comprise at least two spaced apart electrodes; performing session of measurements comprising imposing and alternating electrical current between pairs of said electrodes and obtaining voltage signals representative of a voltage drop thereon; calculating values of skin-electrode resistance for all said electrodes; comparing said calculated values of skin-electrode resistance therebetween, wherein result of the comparison exceeding a predetermined threshold value being representative of a potential failure in at least one of said electrodes.

A method and system for multi-electrode monitoring of an internal electrical impendance of a biological object using placing two arrays of electrodes on opposite sides of the biological object, wherein each of said two arrays comprise at least two spaced apart electrodes; performing session of measurements comprising imposing and alternating electrical current between pairs of said electrodes and obtaining voltage signals representative of a voltage drop thereon; calculating values of skin-electrode resistance for all said electrodes; comparing said calculated values of skin-electrode resistance therebetween, wherein result of the comparison exceeding a predetermined threshold value being representative of a potential failure in at least one of said electrodes.