An electrode configured to provide electrical contact with the skin of a user and configured to be positioned on or near a mastoid region of the user is provided. The electrode comprises an electrically conductive contact configured to receive electrical signals from the skin of the user, and a skin coupler that couples the contact with the skin of the user. The skin coupler comprises an adhesive layer that adhesively engages the skin. The skin coupler also comprises a base region that surrounds the contact, and at least two extension regions that extend away from the base region.

An information processing apparatus according to an embodiment of the present technology includes a determination unit and an output unit. The determination unit determines, on a basis of information related to a usage state of a wearable device, a holding state of the wearable device with respect to an attachment target. The output unit generates and outputs control information for achieving the determined holding state.

Various methods and systems are provided for cerebral diagnosis. In one example, among others, a method includes obtaining EEG signals from sensors positioned on a subject; conditioning data from the EEG signals to remove artifacts; generating a cerebral network model based at least in part upon the conditioned data; determining network features based upon the cerebral network model; and determining a cerebral condition of the subject based at least in part upon the network features. In another example, a method includes determining a recording condition of a positioned EEG sensor and providing an indication of an unacceptable recording condition of the EEG sensor. In another example, a system includes an EEG recording module to acquire signals; a signal conditioning module to condition signal data; a signal analysis module to determine signal features and cerebral network features; and a condition classification module to determine a cerebral condition of the subject.

A system in which a head-mountable wearable device detects a real-time electroencephalographic (EEG) response from a user while the user is performing an activity or exposed to an external stimulus in a real-world (non-clinical) setting. The wearable device performs on-board processing of a detected EEG signal to enable efficient data wireless transfer to a processing unit (e.g. on a smartphone or the like). The processing unit transforms the EEG signal in real time into a meaningful indicator of current mental state, and presents indicator to the user, e.g. in a form able to improve their performance of the activity, promote complementary activities or to enhance or alter their mental state.

A biosignal measurement device includes: a first chopper amplifier circuit that receives a biosignal detected by a measurement electrode contacting a living body, and is chopper-controlled based on a first control signal; and a controller that selectively performs one of a biosignal measurement mode operation for outputting the first control signal having a first frequency to the first chopper amplifier circuit and a test mode operation for outputting the first control signal having a different frequency from the first frequency to the first chopper amplifier circuit.

A concentric ring electrode (CRE) is provided that can sense characteristics of an electric potential, such as its Laplacian, more accurately than previous systems. The disclosed system and methods can optimize estimates of the Laplacian based on potentials measured by the CRE's electrodes, and can optimize the geometry of the CRE, in particular the ring electrodes' radii. Given the CRE's geometrical configuration, the system estimates the Laplacian's dependence on the measured potentials by computing a null space of a matrix associated with a series expansion of the potential. The system determines coefficients for the dependence, wherein a first coefficient is between 10 and 10 times, or between 6.5 and 7.5 times, a second coefficient. The system can optimize ranges for the radii by canceling at least one truncation term of the series expansion, estimating a higher-order truncation term as a function of the radii, and minimizing this estimated function.

Example methods are disclosed herein that include obtaining electroencephalographic (EEG) data from a subject via a device comprising two or more independently adjustable bands, each of the bands having a plurality of electrodes to detect the electroencephalographic data from a brain of the subject, each band selectively rotatable relative to an adjacent band and each band selectively compressible to increase a force of the electrodes against a head of the subject. The example method also includes converting the EEG data into digital EEG signals and conditioning the digital EEG signals. In addition, the example method includes analyzing the digital EEG signals using one or more analysis protocols to determine a mental characteristic of the subject and transmitting the mental characteristic to an output device.

A neural probe comprising an array of stimulation and/or recording electrodes supported on a tape spring-type carrier is described. The neural probe comprising the tape spring-type carrier is used to insert flexible electrode arrays straight into tissue, or to insert them off-axis from the initial penetration of a guide tube. Importantly, the neural probe is not rigid, but has a degree of stiffness provided by the tape spring-type carrier that maintains a desired trajectory into body tissue, but will subsequently allow the probe to flex and move in unison with movement of the body tissue.

An electrode array insertion tool, including an assembly configured to provide direct array insertion functionality and ancillary array insertion functionality to a user thereof. In an exemplary embodiment, the tool includes an extra-cochlea bone conduction actuator system, and the ancillary array insertion functionality is output of vibrations directly to the cochlea by the system.

A determination system includes a head electrode that is located on a left head portion of a user when an intention of the user to move a portion on a right side of a body of the user is detected and that is located on a right head portion of the user when an intention of the user to move a portion on a left side of the body of the user is detected; an ear hole electrode that is located in an ear hole of the user; an electroencephalogram signal measurer that obtains a voltage between the head electrode and the ear hole electrode; and a determiner that determines whether or not a change in the voltage includes the intention to move the portion on the right side of the body or the intention to move the portion on the left side of the body.