A detachable physiological monitoring device includes a detachable electrode and an electrical coupling unit electrically connected to the detachable electrode. The electrical coupling unit includes a flexible substrate, a fabric, and a conductive wire. The flexible substrate has a first surface and a second surface opposite to the first surface, and the flexible substrate has a first opening. The fabric is disposed at the first surface of the flexible substrate. The fabric includes a second opening corresponding to the first opening and a conductive region surrounding the second opening. The conductive wire has a first terminal and a second terminal opposite to the first terminal, and the first terminal is connected to the conductive region. The detachable electrode contacts the conductive region, and is connected to the conductive wire.

An electronic device includes a housing forming an enclosed chamber. The housing has a top portion and a bottom portion. One or more sensors is provided within the chamber and configured to interface with a user to generate physiological data associated with the user. A set of electrodes is provided on the bottom portion of the housing. Each electrode in the set of electrodes is a single member having a corresponding inner electrode portion within the chamber and an outer electrode portion outside the housing. A set of magnets is provided on the bottom portion of the housing.

An electronic device includes a housing forming an enclosed chamber. The housing has a top portion and a bottom portion. One or more sensors is provided within the chamber and configured to interface with a user to generate physiological data associated with the user. A set of electrodes is provided on the bottom portion of the housing. Each electrode in the set of electrodes is a single member having a corresponding inner electrode portion within the chamber and an outer electrode portion outside the housing. A set of magnets is provided on the bottom portion of the housing.

An electronic device wearable on a wrist of a user is provided. The electronic device includes a housing forming an enclosed chamber. The housing has a top portion and a bottom portion. The electronic device further includes one or more sensors, a set of electrocardiogram electrodes, and a set of bioimpedance electrodes separate from the set of electrocardiogram electrodes. The one or more sensors are configured to interface with the user to generate physiological data associated with the user. The set of electrocardiogram electrodes are provided on the bottom portion of the housing for generating electrocardiogram data associated with the user. The set of bioimpedance electrodes are provided on the bottom portion of the housing. In some implementations, the electronic device includes a side touch track on a lateral portion of the housing that cooperates with the electrocardiogram electrodes to generate the electrocardiogram data.

An electronic device wearable on a wrist of a user is provided. The electronic device includes a housing forming an enclosed chamber. The housing has a top portion and a bottom portion. The electronic device further includes one or more sensors, a set of electrocardiogram electrodes, and a set of bioimpedance electrodes separate from the set of electrocardiogram electrodes. The one or more sensors are configured to interface with the user to generate physiological data associated with the user. The set of electrocardiogram electrodes are provided on the bottom portion of the housing for generating electrocardiogram data associated with the user. The set of bioimpedance electrodes are provided on the bottom portion of the housing. In some implementations, the electronic device includes a side touch track on a lateral portion of the housing that cooperates with the electrocardiogram electrodes to generate the electrocardiogram data.

A latching mechanism for connecting a first object to a second object is provided. The latching mechanism includes a groove provided along a surface of the first object. The groove includes a notch. The notch can be centered in the groove. The groove is configured to receive a connective end of the second object, and the notch is configured to lock the connective end of the second object in place. The notch can receive a tab from the connective end of the second object.

In this biological information measurement device, the following are provided within a shield frame 315 in which the interior is shielded from the outside when attached to a sensor sheet 100: a terminal (a spring probe 312) that is connected to a sensor (an electrode 133) of the sensor sheet 100; and an external terminal (a USB terminal 313) for connection to an external device.

An electrode connector adapted for attachment to a biomedical patient electrode by either pinch or snap connection includes a pair of pivotally connected members including a connector body and a jaw pivotally connected to said connector body, with the jaw defining a beveled lower surface that functions to urge the jaw open by engagement of the top surface of an ECG stud thereby allowing the connector to be attached by snap engagement. An electrically conducting plate is disposed at the bottom of the connector to maximize electrical contact with the electrode stud. The jaw member further includes a lip functioning to engage a lower portion of the head of the stud and urge the radially enlarged base of the stud into electrical contact with the bottom surface of said electrically conducting member. An ECG electrode connector in accordance with the present invention may further be fabricated of radiolucent materials.

An electrode connector adapted for attachment to a biomedical patient electrode by either pinch or snap connection includes a pair of pivotally connected members including a connector body and a jaw pivotally connected to said connector body, with the jaw defining a beveled lower surface that functions to urge the jaw open by engagement of the top surface of an ECG stud thereby allowing the connector to be attached by snap engagement. An electrically conducting plate is disposed at the bottom of the connector to maximize electrical contact with the electrode stud. The jaw member further includes a lip functioning to engage a lower portion of the head of the stud and urge the radially enlarged base of the stud into electrical contact with the bottom surface of said electrically conducting member. An ECG electrode connector in accordance with the present invention may further be fabricated of radiolucent materials.

The electrode for recording a physiological electrical signal of a living being made from electrically conductive material and including a body having a front surface and a rear surface for electrical contact, the electrode further including a rigid mounting element attached to the body, at an edge of the rear electrical contact surface and designed so as to produce a removable mounting of the electrode on a recording sensor.