Embodiments described herein relate generally to a portable biometric monitoring device having a central pod, sensor electrodes, and a wearable band. The central pod can be removably coupled to the wearable band. The sensor electrodes can transfer data to an circuit on a printed circuit board (PCB) in the central pod. The circuit can be housed in the central pod and can be configured to process data transferred from the sensor electrodes. The central pod can be electrically coupled to the sensor electrodes via one or more conductive wires while the wearable band is coupled to the central pod. In some embodiments, the central pod can be electronically isolated from the sensor electrodes when the wearable band is not coupled to the central pod. In some embodiments, the one or more conductive wires are substantially encased in the wearable band.

A nametag transmitter is a nametag transmitter that is to be attached to smartwear including an electrode for detecting biological information, the nametag transmitter including: a reception unit for receiving the biological information from the electrode; a wireless communication unit for transmitting the biological information to a data collection apparatus; a display unit for displaying identification information for specifying a user of the smartwear; and a connection portion to be attached to the smartwear. The nametag transmitter is attached to the smartwear in a state in which pairing between the wireless communication unit and the data collection apparatus has been carried out.

A nametag transmitter is a nametag transmitter that is to be attached to smartwear including an electrode for detecting biological information, the nametag transmitter including: a reception unit for receiving the biological information from the electrode; a wireless communication unit for transmitting the biological information to a data collection apparatus; a display unit for displaying identification information for specifying a user of the smartwear; and a connection portion to be attached to the smartwear. The nametag transmitter is attached to the smartwear in a state in which pairing between the wireless communication unit and the data collection apparatus has been carried out.

This detection device is a device for detecting the movement of a human body. The detection device has: a substrate having flexibility; an electric element provided on the substrate and having an electrical characteristic that changes with the movement of the human body; and a semiconductor element that is provided on the substrate, detects a change in the electrical characteristic of the electric element, and outputs a detection value corresponding to the detected result. The substrate is a flexible substrate or a fabric member including conductive fibers, for example.

This detection device is a device for detecting the movement of a human body. The detection device has: a substrate having flexibility; an electric element provided on the substrate and having an electrical characteristic that changes with the movement of the human body; and a semiconductor element that is provided on the substrate, detects a change in the electrical characteristic of the electric element, and outputs a detection value corresponding to the detected result. The substrate is a flexible substrate or a fabric member including conductive fibers, for example.

A textile electrode device, for detection of electrophysiological signals from the skin of a subject, having: a substrate designed to be positioned on the skin; at least a first detection electrode arranged on the substrate; and at least a first conducting element, carried by the substrate and electrically connected to the first detection electrode. The first detection electrode has a plurality of textile fibres, including conductive fibres and, optionally, fibres of a super-absorbent material, arranged in a direction substantially orthogonal to an upper surface of the substrate and reciprocally in contact with each other, so as to ensure uniform electrical contact over the entire first detection electrode. In particular, the first detection electrode is obtained by means of the flocking technique.

An ECG processing system for identifying noisy ECG data segments is provided. The ECG processing system includes a network interface and a processor. The network interface is configured to receive a first collection of ECG data segments from wearable medical devices associated with a plurality of patients, each wearable medical device of the wearable medical devices being configured to be continuously worn by a patient for an extended period of time. The processor is configured to produce a second collection of ECG data segments from the first collection of ECG data segments that excludes noisy ECG data segments.

Devices and methods for electrical potential sensing and influencing are provided. The inventive devices include electroencephalography (EEG), electrocardiogram (EKG), photoplethysmography (PPG), electromyography (EMG), and temperature devices for measuring bio-activity signals from a body. The described devices are designed to include motion dampending, a hybrid non-contact and contact sensing surface and to optimise sensitivity in difficult sensing conditions, such as during movement, through obstructions like hair and clothing, while having a convenient and small form factor. The inventive devices provide for improved sensitivity, adaptability, and noise reduction when compared to other designs. Methods for influencing said bio signals with a device with a hybrid non-contact and contact sensing surface are also described.

Devices and methods for electrical potential sensing and influencing are provided. The inventive devices include electroencephalography (EEG), electrocardiogram (EKG), photoplethysmography (PPG), electromyography (EMG), and temperature devices for measuring bio-activity signals from a body. The described devices are designed to include motion dampending, a hybrid non-contact and contact sensing surface and to optimise sensitivity in difficult sensing conditions, such as during movement, through obstructions like hair and clothing, while having a convenient and small form factor. The inventive devices provide for improved sensitivity, adaptability, and noise reduction when compared to other designs. Methods for influencing said bio signals with a device with a hybrid non-contact and contact sensing surface are also described.

This invention is a dry EEG electrode with an articulated distal base and/or a plurality of articulated conductive proximal protrusions which penetrate between strands of hair for good electromagnetic contact without causing discomfort or skin irritation.