A system for measuring the ECG of a user by having at least two sensors, all of which are attached to only one peripheral of the user. The system may also comprise a controller for determining ECG signals from the data received from the sensors. The system may be in the form of a wearable band on which the sensors and the controller are disposed. The sensors may be capacitive sensors, electrically coupled capacitive sensors, or electrodes. The sensors may be attached to one arm of a user. The sensors may be disposed on the inside and outside of the arm away from each other at the same axial position on the arm. The sensors may be disposed at axially different positions on the arm, for example, one at the wrist and the other at the shoulder of the user.

A system for measuring the ECG of a user by having at least two sensors, all of which are attached to only one peripheral of the user. The system may also comprise a controller for determining ECG signals from the data received from the sensors. The system may be in the form of a wearable band on which the sensors and the controller are disposed. The sensors may be capacitive sensors, electrically coupled capacitive sensors, or electrodes. The sensors may be attached to one arm of a user. The sensors may be disposed on the inside and outside of the arm away from each other at the same axial position on the arm. The sensors may be disposed at axially different positions on the arm, for example, one at the wrist and the other at the shoulder of the user.

A system for providing a standard electrocardiogram (ECG) signal for a human body using contactless ECG sensors for outputting to exiting medical equipment or for storage or viewing on a remote device. The system comprises a digital processing module (DPM) adapted to connect to an array of contactless ECG sensors provided in a fabric or the like. A selection mechanism is embedded into the DPM which allows the DPM to identify body parts using the ECG signals of the different ECG sensors and select for each body part the best sensor lead. The DPM may then produce the standard ECG signal using the selected ECG signals for the different body parts detected. The system is adapted to continuously re-examine the selection to ensure that the best leads are selected for a given body part following a movement of the body part, thereby, allowing for continuous and un-interrupted ECG monitoring of the patient.

A detection apparatus and a method are provided for detecting a respiratory movement of a patient. The detection apparatus includes at least two metallic U-shaped signal coupling elements that are interleaved so that between the signal coupling elements arises at least one coupling point at which a signal may be transferred between the two signal coupling elements. Analysis electronics are configured to detect a change in a received signal produced in a second of the signal coupling elements that is acting as a receiver in the near-field region of the first signal coupling elements as a result of a signal given for one of the signal coupling elements that is acting as a transmitter being coupled into the second of the signal coupling elements, which change indicates the respiratory movement.

A detection apparatus and a method are provided for detecting a respiratory movement of a patient. The detection apparatus includes at least two metallic U-shaped signal coupling elements that are interleaved so that between the signal coupling elements arises at least one coupling point at which a signal may be transferred between the two signal coupling elements. Analysis electronics are configured to detect a change in a received signal produced in a second of the signal coupling elements that is acting as a receiver in the near-field region of the first signal coupling elements as a result of a signal given for one of the signal coupling elements that is acting as a transmitter being coupled into the second of the signal coupling elements, which change indicates the respiratory movement.

A measurement device includes a biosensor that acquires biological information, a pressing force detection component that detects a pressing force produced when the biosensor makes contact with a part of a living body to be measured, and a processor that converts the biological information to a first measurement value, calculates a second measurement value by correcting the first measurement value based on the pressing force, and outputs the second measurement value.

A measurement device includes a biosensor that acquires biological information, a pressing force detection component that detects a pressing force produced when the biosensor makes contact with a part of a living body to be measured, and a processor that converts the biological information to a first measurement value, calculates a second measurement value by correcting the first measurement value based on the pressing force, and outputs the second measurement value.

A system for providing a standard electrocardiogram (ECG) signal for a human body using contactless ECG sensors for outputting to exiting medical equipment or for storage or viewing on a remote device. The system comprises a digital processing module (DPM) adapted to connect to an array of contactless ECG sensors provided in a fabric or the like. A selection mechanism is embedded into the DPM which allows the DPM to identify body parts using the ECG signals of the different ECG sensors and select for each body part the best sensor lead. The DPM may then produce the standard ECG signal using the selected ECG signals for the different body parts detected. The system is adapted to continuously re-examine the selection to ensure that the best leads are selected for a given body part following a movement of the body part, thereby, allowing for continuous and un-interrupted ECG monitoring of the patient.

The technology relates to medical equipment, namely, to a medical chair for recording an electrocardiogram in the first lead («1-lead»), and can be used in medical institutions, pharmacies, public organizations and at home.

Chair for measuring electrocardiogram in the first lead containing: two dry capacitive contact electrodes, each is attached to the appropriate armrest; wherein electrodes are made in the form of handles and configured in such a way as to enable the user to hold onto them with their palms in a sitting position; wherein electrodes are adapted to connect them to the lead cable for connection with the electrocardiograph, wherein electrodes are isolated from the chair frame through a dielectric spacer, wherein the electrocardiograph holder is attached to the chair so that the electrocardiograph secured in the holder is at user eye level.

The technology relates to medical equipment, namely, to a medical chair for recording an electrocardiogram in the first lead («1-lead»), and can be used in medical institutions, pharmacies, public organizations and at home.

Chair for measuring electrocardiogram in the first lead containing: two dry capacitive contact electrodes, each is attached to the appropriate armrest; wherein electrodes are made in the form of handles and configured in such a way as to enable the user to hold onto them with their palms in a sitting position; wherein electrodes are adapted to connect them to the lead cable for connection with the electrocardiograph, wherein electrodes are isolated from the chair frame through a dielectric spacer, wherein the electrocardiograph holder is attached to the chair so that the electrocardiograph secured in the holder is at user eye level.