A biometric information sensor includes a flexible substrate, an adhesive, a heartbeat signal detector, an electrocardiographic signal detector, a pulse wave detector, and a signal processor. The signal processor calculates an electrocardiographic peak estimated value resulting from estimating the wave of an electrocardiographic signal detected by the electrocardiographic signal detector from a heartbeat signal detected by the heartbeat signal detector based on the heartbeat signal and the electrocardiographic signal. The signal processor estimates a pulse wave transmit time based on the calculated electrocardiographic peak estimated value a photoplethysmographic signal detected by the pulse wave detector.

A biometric information sensor includes a flexible substrate, an adhesive, a heartbeat signal detector, an electrocardiographic signal detector, a pulse wave detector, and a signal processor. The signal processor calculates an electrocardiographic peak estimated value resulting from estimating the wave of an electrocardiographic signal detected by the electrocardiographic signal detector from a heartbeat signal detected by the heartbeat signal detector based on the heartbeat signal and the electrocardiographic signal. The signal processor estimates a pulse wave transmit time based on the calculated electrocardiographic peak estimated value a photoplethysmographic signal detected by the pulse wave detector.

An electrocardiography patch is provided. A backing forms an elongated strip with a mid-section connecting two ends of the backing. The mid-section is narrower than the two ends of the backing. An electrocardiographic electrode is provided on each end of the backing to capture electrocardiographic signals. A flexible circuit includes a pair of circuit traces electrically coupled to the electrocardiographic electrodes. A wireless transceiver communicates at least a portion of the electrocardiographic signals.

An emergency cardiac and electrocardiogram (ECG) electrode placement device is disclosed herein. The emergency cardiac and electrocardiogram (ECG) electrode placement device incorporates electrical conducting materials and elastic material into a pad that is applied to a chest wall of a patient, which places multiple electrodes in the appropriate anatomic locations on the patient to quickly obtain an ECG in a pre-hospital setting.

An emergency cardiac and electrocardiogram (ECG) electrode placement device is disclosed herein. The emergency cardiac and electrocardiogram (ECG) electrode placement device incorporates electrical conducting materials and elastic material into a pad that is applied to a chest wall of a patient, which places multiple electrodes in the appropriate anatomic locations on the patient to quickly obtain an ECG in a pre-hospital setting.

One of the methods includes positioning the physiological data acquirer on the body of a mammal with the electrodes exposed to the body; activating a data acquisition mode of operation of the physiological data acquirer and acquiring physiological data from the user when in said data acquisition mode. Another one of the methods includes extracting the acquired data using a data extraction device.

One of the methods includes positioning the physiological data acquirer on the body of a mammal with the electrodes exposed to the body; activating a data acquisition mode of operation of the physiological data acquirer and acquiring physiological data from the user when in said data acquisition mode. Another one of the methods includes extracting the acquired data using a data extraction device.

A sensor assembly includes a housing and a circuit board assembly. The housing includes a first accommodation cavity, a second accommodation cavity, a first connection portion, a second connection portion, and a third accommodation cavity. The first connection portion is connected to the first accommodation cavity and one end of the third accommodation cavity, and the second connection portion is connected to the second accommodation cavity and the other end of the third accommodation cavity. The circuit board assembly is accommodated within the first accommodation cavity, the second accommodation cavity, the first connection portion, the second connection portion and the third accommodation cavity. The width of the first connection portion and the second connection portion is less than the width of the first accommodation cavity, the second accommodation cavity and the third accommodation cavity. The first connection portion and the second connection portion are each provided with a buffer groove along the width direction.

An extended wear electrocardiography and physiological sensor monitor is provided. An electrode patch includes an integrated flexible circuit having a single piece of material that includes a longitudinal midsection between upper and lower ends and a mirror image shape of the upper end extending from at least a portion of one side of the upper end that runs substantially parallel to the midsection and folds over the upper end. A receptacle is adhered on an outward surface of the mirror image when the integrated circuit is folded over the upper end. One electrode is positioned on a contact surface of the integrated circuit on the upper end and another electrode is positioned on the contact surface on the lower end. A battery is directly adhered to the outward surface of the mirror image and positioned under the receptacle. A monitor is configured to be removably secured in the receptacle.

An extended wear electrocardiography and physiological sensor monitor is provided. An electrode patch includes an integrated flexible circuit having a single piece of material that includes a longitudinal midsection between upper and lower ends and a mirror image shape of the upper end extending from at least a portion of one side of the upper end that runs substantially parallel to the midsection and folds over the upper end. A receptacle is adhered on an outward surface of the mirror image when the integrated circuit is folded over the upper end. One electrode is positioned on a contact surface of the integrated circuit on the upper end and another electrode is positioned on the contact surface on the lower end. A battery is directly adhered to the outward surface of the mirror image and positioned under the receptacle. A monitor is configured to be removably secured in the receptacle.